Powtran PI8000, PI8100 User Manual

Foreword

Thank you very much for purchasing PI8000,PI8100 Family Frequency Inverters.This family
is designed based on the experience of POWTRAN Company in the professional manufacture and
sale of the products, and suitable for general-purpose machine, fan/pump drive, medium frequency
drive and heavy load machine.

This product adopts the advanced sensorless vector control technology, combined with China
local frequency invenrter application features to achieve high-performance V/F control (dead-time
compensation + auto-torque upgrade + Slip Compensation) and high-performance non-sense vector
control, and high-performance speed sensorless vector control.

This product adopts the advanced sensorless vector control technology, combined with the
application of inverter technology in China features to achieve high-performance V/F control
(dead-time compensation + auto-torque upgrade + Slip Compensation) and high-performance
non-sense vector control, and high-performance speed sensorless vector control.

This User’s Manual includes PI8000/PI8100, the general purpose control and special purpose
control . The general purpose control ha F, G, M and H; The special purpose control has S, T and
Z:

F: FLOW LOAD

G: GENERAL LOAD

M: MEIDDLE LOAD

H: HEAVY LOAD.

S: TEXDRIVE.

T: WINDLASS.

Z: JETDRIVE.

Please contact the local dealers or directly contact our company.

Please keep this user’s manual in good condition,for it will be helpful to the repair,maintenance,

and applications in the future.

For information about other product, please visit our website: http://www.powtran.com.

CONTENTS

Section I Inspection & Safety Precautions......................................................1

Section II Installation & Standby Circuit.........................................................3

Section III Operating Keyboard ......................................................................13

Section IV Test Running..................................................................................21

Section V Parameter Function Table ..............................................................24

Section VI Fault Diagnosis & Solutions ........................................................100

Section VII Standard Specifications................................................................102

Section VIII Maintenance ................................................................................117

Section IX Options ........................................................................................ 119

Section X Quality Assurance........................................................................123

Appendix I RS485 Communication Protocol .................................................124

Appendix II Instruction of the Proportional Linkage Function........................ 139

Appendix III RS485 PG Card Instruction .........................................................142

Appendix IV Converter Water Supply Controller Instruction ...........................144

Sec

o

Section I Inspection & Safety Precaution

Section I. Inspection & Safety Precautions

POWTRAN PI8000 frequency inverters have been tested and inspected before leaving the
manufacturer. Before unpacking the product, please check if its package is damaged due to careless
transportation, and if the specifications and type of the product complies with the order. Please
contact the supplier of POWTRAN products if any problems are found.

1-1. Inspection after Unpacking

※ Inspect that the contents are complete (one unit of PI8000/8100 frequency inverter, one

operation manual(with a copy of warranty card), one maintaince tips card).

※ Check the nameplate on the side of the frequency inverter to ensure that the product you

have received is right the one you ordered.

1-1-1. Name plant Instruction 1

AC Motor Drivers Model

Input Spec.

Output Spec.

Serial No.& Bar Code

TYPE:
SOURCE:
OUTPUT:

POWTRAN TECHNOLOGY CO.,LTD.

1-1-2. Model description 2:

PI 800 0 b 004 G 3

POWTRAN
INVERTER

Serial Name

PI800: PI8000 Serial
PI801: PI8100 Serial

class code:
0: normal configuration

1:spetial 1 configuration

2:spetial 2 configuartion

type code
a: normal (elided)

b: inhanced m: mini

d: single board

Applicable motor
capacity()

：

7R5: 7.5KW

e.g.
4: 4KW

1-2. Safety Precautions

※ Never connect the A.C. power supply to the output terminals (U, V, W) of the frequency

inverter.

※ Fix and lock the panel before supplying power so as to avoid the danger caused by the poor

capacity or other components inside the inverter.

※ After the power supply is switched on, do not perform wiring or check, etc.
※ Don’t touch the circuit boards or its parts or components in the inverter when it is powered,

so as to avoid danger of electric shock.

PI8000 004G3

3φ 380V 50-60Hz

4KW 8.5A 0.00-800.0Hz

Z1001A00001

Input voltage level
1: single-phase 220V 2: 3-phase 220V
3: 3-phase 380V 4: 3-phase 460V
5: 3-phase 575V 6: 3-phase 660V
9: 3-phase 1140V

Function Code()
General Type F: Flow load

Special Type S:
TEXDRIVE

1

G: General load
M: Middle load
H: Heavy load

T: WINDLASS
Z: JETDRIVE

※ If the power supply is switched off, do not touch the PCB or other parts inside the inverter

Section I

ti
n I

within 5 minutes after the keyboard indicator lamp goes off, and you must check by using
the instrument that the inverter has completely discharged all its capacity before you start to
work inside the inverter. Otherwise, there will be the danger of electric shock.

※ The static electricity in human body will cause serious damage to the MOS field effect

transistor in the inverter. Please keep your hands away from the PCB, IGBT and other
internal parts before taking actions to prevent static electricity. Otherwise, faults may be
caused.

※ In use, the earthing terminal (

) of the frequency inverter must be grounded to the earthing
connections correctly and securely according to the national electrical safety specifications
and other applicable standards.

※ Please don’t shut off the unit by turning off the power supply. Turn off the power supply

after the motor has stopped its operation.

※ Meet CE standard with EMI filter.

1-3. Application

※ Powtran inverter is generally applied to 3 phase AC asynchronism motors.
※ Powtran inverter is applied to the admisive occasion, the occasion where is not admissive

may lead to fire, electric shock, explosion and so on.

※ If the inverter seizes up when it is applied to the equipment which may lead danger (e.g. lift

tools of transportation, aviation system, saftety equipment, etc), it should be managed
carefully. Do inquire the factory when it happens.

Only the well-trained personnel are allowed to use this unit, and such

personnel must read through the parts of this manual relating to the safety,

installation, operation and maintenance before using the unit. The safe

operation of this unit depends on correct transport, installation, operation

and maintenance!

2

Section II Intallation & Standby Circuit

Section II. Installation & Standby Circuit

2-1. Conditions for Use

1) Ambient temperature -10 ~40 .℃℃

2) Avoid electromagnetic interference and keep the unit away from the interference source.

3) Prevent dropping water, steam, dust, powder, cotton fiber or fine metal powder from entering it.

4) Prevent oil, salt and corrosive gas from entering it.

5) Avoid vibration.

6) Avoid high temperature and moisture and avoid being wetted due to raining, with the humidity

below 90%RH (not dewing).

7) Prohibit the use in the dangerous environment where inflammable or combustible or explosive

gas, liquid or solid exists.

2-2. Installation

The frequency inverter must be installed by wall hooking in the indoor room with adequate
ventilation, with enough space left between it and the adjacent objects or damper (walls) surrounding
it, as shown in the below figure:

OUT

150mm

or more

DIGITAL PANEL

FWD REV

+

-

S00 设定频率

0.00 0.0

S01 实际频率
S10 PID反馈值

50mm 50mm

or more

PRG

SET

ESC STOP/RESET

OUT

ALARM

Hz

%

°C

A

s

V

-

E
N
T

E
R

+

FWDMF2MF1

or more

AIR

2-3-1. PI8000 Diagram

1. Wiring diagram 11kW ~15kW and below (8N2)

Section II

Section II

WARNING

Read the operation manual before adjust or inspect.

High voltage inside.Maintained by the well-trained
personnel.

Confirm the input and output dc control cables are
well connected.

Adjust or inspect the inner circuits after power down
and discharge.

IN IN

150mm

or more

2-3. Wiring

The wiring of frequency inverter includes two parts: main circuit and control circuit. The user

must ensure correct connections according to the following connection diagram.

3

4

Section II Inspection & Standby Circuit

Section II Intallation & Standby Circuit

2. Wiring diagram 18.5kW~355kW(8N3/8N4 /8N5 /8N6 /8N7 /8N8 /8N9 /8NA /8NB)

Section II

2-3-2. PI8100 Diagram

1. Wiring diagram 11kW and below (7N2 /7N3 /7N4)

Section II

5

6

2-4. Main Circuit Terminals(G Series)

2-4-1. PI8000 Main Circuit Terminals

1. 11~15kW(380V)Main Circuit Terminals

2. 18.5~37kW(380V)Main Circuit Terminals

Section II Inspection & Standby Circuit

Section II

Section II Intallation & Standby Circuit

Section II

2-4-2. PI8100 Main Circuit Terminals

1. 7.5kW below(380V)Main Circuit Terminals

3. 45~250kW(380V)Main Circuit Terminals

AC Input Line
Terminals

R/L1

DC+1 DC+2

DC+1/DC+2:DC Resistance
DC+2/DC- :Braking unit

DC-

S/L2

T/L3

Motor connection

W/T3V/T2U/T1

/E

Note: DC+1/DC+2 Standard setting is short circuit; if it is with external reactance, please disconnect

and then connect it.

4. 280~355kW(380V)Main Circuit Terminals

7

Note: The above kW categaries are for G type inverter.
2-4-3. Terminal Function

Terminal Description Functions

R/L1

S/L2

T/L3

B1, B2

U/T1

V/T2

W/T3

DC+2, DC- DC Bus output Connect the brake brake unit.

DC+1, DC+2

Power input for
frequency inverter

Grounding point Grounded to the earth

Connection point for
braking resistance

3 Phase Output Connected to 3-phase motor

DC reactance connection
terminal.

Connected to 3-phase power
(Single input connected to R, T)

Connect brake resistance

Connect DC reactance (No short circuit).

2-5. Control Circuit Terminals
2-5-1. Control Circuit Terminals Description

Classify Terminal Description Functions

Input
signal

DI1 DI1 Input Terminal

DI2 DI2 InputTerminal

Multi-functions input terminal.For details
Please read o36~o46

8

Section II Inspection & Standby Circuit

Section II Intallation & Standby Circuit

Assistant
Power

Output
signal

Analog
input
signal

DI3 DI3 Input Terminal

DI4 DI4 Input Terminal

DI5 DI5 Input Terminal

DI6 DI6 Input Terminal

DI7 DI7 Input Terminal

DI8 DI8 Input Terminal

PLC

24V Power positive

COM Common terminal

SPA/COM Output signal 1

SPB/COM Output signal 2

TA1/TB1/TC1 Output signal 3

TA2/TB2/TC2 Output signal 4

+10V, GND Analog power +10V, 50mA

AI1

AI2

AI3

DA1

PLC Control
Ter mi na l

Multifunction Analog
input signal 1

Multifunction Analog
input signal 2

Multifunction Analog
input signal 3

More function analog
output 1

Enter a valid polarity can be controlled by o47
DI1~DI4 Drive model can be controled by JP4
Above 11kW:
DI5~DI8Drive model can be controled by PLC
output terminal

DI6 can as digital pulse input

Below 11kW:
DI5~DI6Drive model can be controled by PLC
output terminal

DI6 can as digital pulse input

PLC Control DI5~DI8 Drive model
Drain Drive : PLCconnect 24VDC or externa
lpower
Source Drive: PLC connect COM

The biggest output 24V/200mA, Can not
connect COM with GND in any situation

Open Collector signal when the output action
(24VDC/50mA)
Common terminal COM , the output function
can set by o21, o22
SPA ,SPB provide hi-speed pulse output fun ­ction.
After setting functions by o61~o64,Frequency
inverter will take effect again.

TA1-TC1open, TB1-TC1close, the output fun ­ction can set by o23

TA2-TC2open, TB2-TC2close, the output
function can set by o24

JP5 cut/JP3 1-2: -10V~+10V
JP5 cut/JP3 2-3: 0~10V
JP5 connect: 0~20mA can be regulated
o00/o01 Set the input voltage / current range
o06/o07 Set the input signal corresponding to
set value

JP6cut: 0~10V
JP6connect: 0~20mA can be regulated
o02/o03can set input voltage/ current arrange
o08/o09 Set the input signal corresponding to
set value

JP7cut: 0~10V
JP7connect: 0~20mA can be regulated
o04/o05can set input voltage/ current arrange
o10/o11 Set the input signal corresponding to
set value

JP1 1-2: 0~20mA
JP1 2-3: 0~10VDC
o15 Set analog output analog functions
o17/o18set the output signal arrange

9

Section II

JP2 1-2: 0~20mA

DA2

2-5-2. Control circuit terminal

Section II

More function analog
output 2

JP2 2-3: 0~10VDC
o16 Set analog output analog functions
o19/o20 set the output signal arrange

1. 8KLCB Control circuit terminal

2. 8KSCB Control circuit terminal

2-6. Connection Precautions

※ Don’t install power factor capacitance or resistance-capacitance absorbing device between

the output terminals U, V, W of the frequency inverter.

※ To disassemble or replace the motor, the input power supply must be turned off for the

frequency inverter.

※ Do not drop Metal scrap foam or lint into the frequency inverter, otherwise the machine will

be faulted.

※ The motor or power supply can be switched on/off only after the inverter stops its output.

※ In order to minimize the effect of electromagnetic interference, a surge absorbing device

should be installed if used electromagnetic contactor and relay, etc. is near to the frequency
inverter.

※ For external control of frequency inverter, a isolation device should be used for the control

lines or screened cable should be used.

※ A screened cable should be used as the signal connection line for input command and must

be routed separately as well, and it had better be installed far from the main circuit.

※ When the carrier frequency is less than 3kHz, the distance between the frequency inverter

and motor must not be greater than 50 meters (maximum). When it is above 4kHz, this
distance should be reduced. The cable for this connection had better be laid in metal conduit.

※ If the frequency inverter is equipped with peripheral devices (such as filter, reactor), first

measure its insulation resistance to the earth with 1000V megohm meter, and ensure the
resistance value is not below 4M.

10

Section II Inspection & Standby Circuit

Section II Intallation & Standby Circuit

※ If the frequency inverter must be started frequently, don’t switch off its power supply, and

the operator must start or stop the inverter by using the COM/FWD of the control terminal
or Keyboard or RS485, in order to avoid damage to the bridge rectifier.

※ Don’t connect A.C. input power to the output terminals U, V, W of the frequency inverter.

※ In order to prevent unexpected accidents, earthing terminal E or

must be grounded to the

earth securely (the grounding resistance should be below 100). The cable size should be
greater than half of below- mentioned corresponding cable size; otherwise current leakage
will happen possibly.

※ For wiring of main circuit, please refer to national rule.

※ Capacity of the motor should be equal to or smaller than that of the inverter.

※ Specification of MCCB、electric cable and contractor

Type MCCB(A)

In/out Cable

(Copper Core)mm2

Rated Operational Current Of

Contractor A(voltage:380V or 220V)

PI8100 R40G2 10A 1.5 10

PI8100 R75G2 16A 2.5 10

PI8100 1R5G2 20A 2.5 16

PI8100 2R2G2 32A 4 20

PI8100 004G2 40A 6 25

PI8100 5R5G2 63A 6 32

PI8000 7R5G2 100A 10 63

PI8000 011G2 125A 10 95

PI8000 015G2 160A 25 120

PI8000 018G2 160A 25 120

PI8000 022G2 200A 25 170

PI8000 030G2 200A 35 170

PI8000 037G2 250A 35 170

PI8000 045G2 250A 70 230

PI8000 055G2 315A 70 280

PI8000 R75G3 10A 1.5 10

PI8000 1R5G3 16A 1.5 10

PI8000 2R2G3 16A 2.5 10

PI8000 004G3 25A 2.5 16

PI8000 5R5G3 25A 4 16

PI8000 7R5G3 40A 4 25

PI8000 011G3 63A 6 32

PI8000 015G3 63A 6 50

PI8000 018G3 100A 10 63

PI8000 022G3 100A 10 80

PI8000 030G3 125A 16 95

Section II

PI8000 037G3 160A 25 120

PI8000 045G3 200A 35 135

PI8000 055G3 250A 35 170

PI8000 075G3 315A 70 230

Section II

PI8000 093G3 400A 70 280

PI8000 110G3 400A 95 315

PI8000 132G3 400A 95 380

PI8000 160G3 630A 150 450

PI8000 187G3 630A 185 500

PI8000 200G3 630A 240 580

PI8000 220G3 800A 150*2 630

PI8000 250G3 800A 150*2 700

PI8000 280G3 1000A 185*2 780

PI8000 315G3 1200A 240*2 900

PI8000 355G3 1280A 240*2 960

PI8000 400G3 1380A 185*3 1035

PI8000 500G3 1720A 185*3 1290

2-7. Standby circuit

When the fault or trip of the inverter may cause great loss or accident, please add the standby circuit.

Note:confirm and test the running characteristic of the standby circuit, in order to ensure the industrial

phase and the converter phase are in the same direction.

MCC1

U

V
W

MCC2

M
3~

3-PHASE
AC POWER
SUPPLY

R
S
T

R

S
T

PI8000

Inverter

Interlock relay

11

12

Sec

o

Section III Operating Keyboard

Section III. Operating Keyboard

3-1. Operating keyboard

3-1-1. JP6E8000 specification and function description(Standard)

Monitor Select 1 Numerical Display
* display the corresponding values of the

function under query status
* display fault code under fault condition
* display the object set byA00 monitor

select while running

Positive And Negative Sign Indication
Light
* just for monitor sel ect

Monitor Select 2 Numerical Disp lay

Parameter Setting/Shift Key
* start to change parameter
* Functions value adjustments
Modification bit

Multi-function Key MF1/MF2
* MF1 define functions through parameter
A43
* MF2 define functions through parameter
A44
* A43/A44=0 MF defined as plus function
* A43/A44=1 MF defined as minus function
* A43/A44=2 MF defined as free stop
function
* A43/A44=3 MF defined as forward
function
* A43/A44=4 MF defined as reverse
function
* A43/A44=5 MF defined as Punctuality
dynamic function
* A43/A44=6 MF defined as Anti-Jog
function
* A43/A44=7 MF defined as Jog function
* A43/A44=8 MF defined as Up function
* A43/A44=9 MF defined as Down function

Reverse Indication Li ght

：

reverse indication

* ON
* OFF

：

not reverse indication

：

reverse accelerating

* FLASH

Forward Indication Light
* ON

：

forward indication

：

not forward indication

* OFF

：

forward accelerating

* FLASH

DIGITAL PANEL

FWD REV ALARM

+

-

PRG

SET

Acceleration Select/Par ameter

Setting Key

* press SET key and rotate JOG key

while selecting parameter, the

parameter location changes to 10
* finish and save the value changes
* change the object under monit or

Alarm Indication

* ON
* OFF
* FLASH

MF1 MF2 FWD

ESC

STOP/RESET

Quit Key
* exit the revisement of

parameter

* reture to displaying menu

from submenu or functional
menu

* exit default state

Light

fault was not
confirmed

Hz

%

A

V

-

：

faulty

：

good

：

previous

℃

s

E
N

T
E
R

ENTER

+

* have the same function with PRG/

refer to explaination of key PRG/

* Invalid in the monitoring state

Potentiometer Key
* under checking state, the

* under revising state, the edit bit

* under monitoring, setting
frequency to increas e or decrease

Data Unit Prompt Light
*composed of three indication

，

located on the right side of

lights
the LED digital tube
status corresponding to the six
units
parameters displayed by LED
*the correspondence is as
following

UNIT

Hz

%

A

S

V

NO UNITS

UNIT

Hz

%

A

S

V

function items value has been in
increment or decrement

of function items value has been
in increment or decrement

，

，

indicate the unit of the

：

UNIT

UNIT

Hz

Hz

%

%

A

A

°C

°C

S

S

V

V

Hz

UNIT

UNIT

Hz

Hz

%

%

A

A

°C

°C

S

S

V

V

%

Forward running k ey
* drive forward running

Reset /Stop Key
* drive stop running
* Exception Reset
* fault confirmation

Display

°C

°C

°CS

。

UNIT

Hz

%

A

S

V

3-1-2. JP6C8000 keyboard specification and function description(Optional)

Monitor Select 1 Numerical Display
* display the corresponding values of the

function under query status
* display fault code under fault condition
* display the object set byA00 monitor

select while running

Section III

°C

VA

ON

OFF

，

Positive And Negative Sign Indication Light
* just for monitor select

Monitor Select 3 Numerical Display

ti

A00 Monitor Select 1

n III

Monitor Select 2 Numerical Display

A01 Monitor Select 2

A02 Monitor Select 3

Parameter Setting/Shift Key
* start to change parameter
* Functions value adjustments

Modification bit

Multi-function Key MF1/MF2
* MF1 define functions through parameter

A43
* MF2 define functions through parameter

A44
* A43/A44=0 MF defined as plus function
* A43/A44=1 MF defined as minus function
* A43/A44=2 MF defined as free stop

function
* A43/A44=3 MF defined as forward

function
* A43/A44=4 MF defined as reverse

function
* A43/A44=5 MF defined as Punctuality

dynamic function
* A43/A44=6 MF defined as Anti-Jog

function
* A43/A44=7 MF defined as Jog function
* A43/A44=8 MF defined as Up function
* A43/A44=9 MF defined as Down function

Reverse Lndication Light

：

reverse indication

* ON

：

not reverse indication

* OFF
* FLASH

：

reverse accelerating

Forward Indication Light
* ON

：

forward indication

：

not forward indication

* OFF

：

forward accelerating

* FLASH

DIGITAL PANEL

FWD REV ALARM

+

-

S00 Set Fre.

0.00

0.5
1 Actual Fre.
2 Motor AC

PRG

MF1 MF2

SET

ESC

Acceleration Select/Parameter

Setting Key

* press SET key and rotate JOG key

while selecting parameter, the

parameter location changes to 10
* finish and save the value changes
* change the object under monitor

Alarm Indication

Light

：

* ON
* OFF
* FLASH

fault was not
confirmed

Hz

%

A

s

V

-

FWD

STOP/RESET

Quit Key
* exit the revisement of

parameter

* reture to displaying menu

from submenu or functional
menu

* exit default state

faulty

：

good

：

previous

℃

E
N

T
E
R

ENTER

+

* have the same function with PRG/

refer to explaination of key PRG/

* Invalid in the monitoring state

Potentiometer Key
* under checking state, the

function items value has been in
increment or decrement

* under revising state, the edit bit

of function items value has been
in increment or decrement

* under monitoring, setting

frequency to increase or decrease

Data Unit Prompt Light
*composed of three indication

，

located on the right side of

lights
the LED digital tube
status corresponding to the six
units
parameters displayed by LED
*the correspondence is as
following

UNIT

Hz

%

A

S

V

NO UNITS

UNIT

Hz

%

A

S

V

，

Display

，

indicate the unit of the

：

UNIT

UNIT

Hz

Hz

%

%

A

A

°C

°C

°C

S

S

V

V

Hz

UNIT

UNIT

Hz

Hz

%

%

A

A

°C

%

Forward running key
* drive forward running

°C

°C

S

S

V

V

°CS

Reset /Stop Key
* drive stop running
* Exception Reset
* fault confirmation

。

UNIT

Hz

%

A

°C

S

V

VA

ON

OFF

，

13

14

Section III Operating Keyboard

Sec

o

Section III Operating Keyboard

3-2. Example for parameters set

3-2-1. F01 keyboard set the frequency from 50.00Hz to 25.00Hz.

PRG

S00 Set Fre.

0.00

0.00

0.00

0.0

0.0

adjust the value
of parameter
revisement

0.0

1 Actual Fre.
2 Motor AC

F01Fre. Set By K

1 Actual Fre.
2 Motor AC

Potentiometer

F01Fre. Set By K F01Fre. Set By K

1 Actual Fre.
2 Motor AC

1. Under monitoring status, press

F00-63 Basic FG

One Times

ENTER
adjust the
parameters

One Times

PI8000 G00
1 Actual Fre.
2 Motor AC

PRG

F01Fre. Set By K F01Fre. Set By K

Or

0.00
1 Actual Fre.
2 Motor AC

SET

0.00
1 Actual Fre.
2 Motor AC

PRG

2. Through potentiometerSwitch to F00-63 Basic FG;

3. Press

PRG

, or ENTER, enter into F00-63 Basic FG parameter group to query status;

4. Through potentiometerSwitch to F01Fre. Set by K;

5. Press

6. Through

PRG

, or ENTER, enter into F01 Fre. Set by K parameter modify status;

PRG

, or ENTER , adjust the value is modified bit;

7. Through potentiometerHas been modified to adjust the bit values;

8. Finish the adjustment, press

SET

status;

9. Press

ESC

to exit to previous menu .

PRG

F00 Control Mode

Or

0.0

0.0

ENTER

One Times

Potentiometer

PRG

Or

ENTER

One Times

0.00
1 Actual Fre.
2 Motor AC

0.00
1 Actual Fre.
2 Motor AC

0.0

Functional
adjustment
item

0.0

into parameter group to query status;

;if cancle the change, press

15

ESC

to escape to the modify

Section III

3-2-2. Parameter upload to the keyboard

Parameter Item Description

N function 0

System parameter upload to the memory area1 in the keyboard 1

y01 parameter upload

to the keyboard

ti
n III

S00 Set Fre. F00-63 Basi c FG

0.00
1 Actual Fre.
2 Motor AC

y01 P Upload K

0.00
1 Actual Fre.
2 Motor AC

Potentiometer

y01 P Upload K

0.00
1 Actual Fre.
2 Motor AC

0.0

0.0

to adjust the
value of
resivement

0.0

System parameter upload to the memory area2 in the keyboard 2

System parameter upload to the memory area3 in the keyboard 3

System parameter upload to the memory area4 in the keyboard 4

Clear memory area in the keyboard1, 2, 3, 4 5

PRG

One Times

ENTER

One Times

PI8000 G00
1 Actual Fre.
2 Motor AC

PRG

y01 P Upload K y00 Reset SP

Or

0.00
1 Actual Fre.
2 Motor AC

SET

P Upload K

USE MEMORY 3RD

100%-END
STOP-END

0.0

Potentiometer

Potentiometer

Upload
Finished

y00-23 System FG

PI8000 G09
1 Actual Fre.
2 Motor AC

PRG

One Times

0.00
1 Actual Fre.
2 Motor AC

y01 P Upload K

0.00
1 Actual Fre.
2 Motor AC

Example . System parameter upload to the memory area3 in the keyboard

PRG

1. Under monitoring status, press

into parameter group to check status;

2. Through potentiometerSwitch to y00-23 System FG;

3. Press

PRG

, or ENTER, enter into y00-23 System FG parameter group to check status;

4. Through potentiometerSwitch to y01P Upload To K;

5. Press

PRG

, or ENTER , enter into y01P Upload To K parameter modify status;

6. Through potentiometer adjust value to be 3 ;

7. Finish the adjustment, press

change, press

8. Press

ESC

to escape to the modification status;

ESC

to exit to previous menu.

SET

;the speed for upload will display on the LED;if cancle the

16

0.0

0.0

Section III Operating Keyboard

Sec

o

Section III Operating Keyboard

3-2-3. Reset system parameters

Parameter Item Description

N function 0

memory area1 in the keyboard to reset system parameter 1

y00 Reset system

parameters

memory area2 in the keyboard to reset system parameter 2

memory area3 in the keyboard to reset system parameter 3

memory area4 in the keyboard 1to reset system parameter 4

Use the factory setting reset system parameter 5

PRG

S00 Set Fre. F00-6 3 Basic FG

0.00

1 Actual Fre.

2 Motor AC

0.00

1 Actual Fre.

2 Motor AC

SET

P Donload K

USE MEMORY 3RD

100%-END
STOP-END

0.0

0.0

One Times

One Times

Potentiometer

to adjust
the value
of
resivement

Download
Finished

PI8000 G00
1 Actual Fre.
2 Motor AC

y00 Reset SP

0.00
1 Actual Fre.
2 Motor AC

y00 Reset SP

0.00
1 Actual Fre.
2 Motor AC

0.0

0.0

Potentiometer

PRG

One Times

y00-23 System FG

PI8000 G09
1 Actual Fre.
2 Motor AC

PRG

One Times

y00 Reset SPy00 Reset SP

0.00
1 Actual Fre.
2 Motor AC

0.0

Example 1: memory area3 in the keyboard 1 to reset system parameter

PRG

1. Under monitoring status, press

into parameter group to query status

2. Through potentiometerSwitch to y00-23 System FG;

3. Press

PRG

, or ENTER, enter into y00-23 System FG parameter group to query status;

4. Through potentiometerSwitch to y01P Upload To K;

5. Press

PRG

, or ENTER, enter into y00 Reset SP parameter modify status;

6. Through potentiometer adjust to 3 ;

7. Finish the adjustment, press

change, press

8. Press

ESC

;

ESC

to exit to previous menu.

SET

;the speed for download will display on the LED;if cancle the

Section III

Example 2 Clear memory area 1, 2, 3, 4 in the keyboard

PRG

S00 Set Fre. F00-63 Ba sic FG y00-23 System FG

0.00
1 Actual Fre.
2 Motor AC

ti
n III

y01P Upload To K y01P Upload To K

0.00
1 Actual Fre.
2 Motor AC

Potentiometer

y01P Upload To K y01P Upload To K y01P Upload To K

0.00
1 Actual Fre.
2 Motor AC

One Times

0.0

PRG

Or

0.0

ENTER

adjust the value
of parameter
revisement

SET

One Times

0.0

PI8000 G00
1 Actual Fre.
2 Motor AC

0.00
1 Actual Fre.
2 Motor AC

0.00
1 Actual Fre.
2 Motor AC

1. Under monitoring status, press

Potentiometer

PI8000 G09
1 Actual Fre.
2 Motor AC

PRG

One Times

Potentiometer

y00 Reset SP

0.0

Clearance
Finished

0.0

PRG

into parameter group to check status

0.00
1 Actual Fre.
2 Motor AC

0.00
1 Actual Fre.
2 Motor AC

0.0

0.0

2. Through potentiometerSwitch to y00-23 System FG;

3. Press

PRG

, or ENTER, enter into y00-23 System FG parameter group to check status;

4. Through potentiometerSwitch to y01P Upload To K;

5. Press

PRG

, or ENTER , enter into y01P Upload To K parameter modify status;

6. Through potentiometer adjust to 5 ;

7. Finish the adjustment, press

cancle the change, press

8. Press

ESC

to exit to previous menu.

SET

;the speed for Clear memory area will display on the LED;if

ESC

;

3-2-4. F02 the main set mode of set frequency is set to 4, keyboard potentiometer setting !

1. Under monitoring status, Through potentiometer adjust the frequency, the resolution ratio
potentiometer is 0.05Hz.

2. Range of set frequency can be set with the following parameters:

Parameter item Description

F12 max. frequency

Inverter output maximum frequency allowed Setting range:

10.00~320.00Hz

17

18

Section III Operating Keyboard

Sec

o

Section III Operating Keyboard

A45 keyboard potentiometer
setting X1

A46 keyboard potentiometer
setting X2

A47 keyboard potentiometer
setting value

A48 keyboard potentiometer
setting X1correspond to Y1

A49 keyboard potentiometer
setting X2 correspond to Y2

S00 setting frequency

Keyboard potentiometer setting the start value
Setting range: 0~100%

Keyboard potentiometer setting the end value
Setting range: 0~100%

Display the value of potentiometer setting, range: A45~A46
Also can set diretly, Setting range: A45~A46

Keyboard potentiometer setting the starting point for the corresponding
value
Setting range: -100%~+100%

Keyboard potentiometer settings corresponding to the value of the end
Setting range: -100%~+100%

Displays the current size of the set frequency,through the potentiometer
setting
Setting range: F12*A48~ F12*A49

Example:

F12=50.00Hz, A45=0%, A46=100%, A47 Shows the value of potentiometer settings 0%~100%,

Numerical size can be adjusted by potentiometer.

(1) when A48=0%, A49=+100%, S00 Set Fre.range 0.00Hz~50.00Hz.

(2) when A48=0%, A49=+50%, S00 Set Fre.range 0.00Hz~25.00Hz.

(3) when A48=-100%, A49=+100%, S00 Set Fre.range -50.00Hz~50.00Hz.

Note: when the motor is in -50.00~0Hz realise reverse, another setting

F45 Ten bit motor forward inverse as

1 Command priority: Analog given positive and negative values, on the F45 details refer to F45

Parameter Description

3-2-5. F02 the main set mode of set frequency is set to 1, AI1 external analog given.

1. Under monitoring status, Through external analog input terminal Al1 adjust the frequency, the
resolution ratio is 0.01Hz.

2. Set the frequency range can be set with the following parameters:

Parameter Item Description

F12 most frequency

o00 AI1 input X1

o01 AI1 input X2

o06 AI1 input X1

correspond to Y1

o07 AI1 input X2

correspond to Y2

S00 frequency setting

Inverter speed adjustment’s allowed maximum output frequency Sett -

ing range: 10.00~320.00Hz

Keyboard potentiometer setting the start value

Setting range: 0~100%

Keyboard potentiometer setting the end value

Setting range: 0~100%

Keyboard potentiometer setting the starting point for the corresponding

value

Setting range: -100%~+100%

Keyboard potentiometer settings corresponding to the value of the end

Setting range: -100%~+100%

Display the frequency,Through out analog input terminal Al1 adjust the

frequency

Section III

Setting range: F12*o06~ F12*o07

Example:

F12=50.00Hz, o00=0%, o01=100%,

(1) When o06=0%, o07=+100%, S00 Set Fre.range 0.00Hz~50.00Hz.

(2) When o06=0%, o07=+50%, S00 Set Fre.range 0.00Hz~25.00Hz.

(3) When o06=-100%, o07=+100%, S00 Set Fre.range -50.00Hz~50.00Hz.

Note: When realize the motor reverse in -50.00~0Hz。

ti
n III

F45Ten bit motor forward reverse as

1 Command priority: Analog given positive and negative values, on the F45 details see F45

Parameter Description

19

20

Sec

o
V

Section IV Test Runing

Section IV. Test Running

● Failure occurred when test running, Please take reference of fault diagnosis in 6-1 to get rid

of the breakdown

● Inverter parameters have a strong adaptive ability, in general b11 = 1 calculation of electrical

parameters with the name plate, on this basis, a little manual adjustment can get you
high-performance vector control.

● Only when the motor completely without the load can set b11=3motor rotation measurements

● Before the electrical parameter measurement finished, inverter can have the ourput voltage

any time, please ensure the safety.

Section IV

ti
n I

test

running

power voltage inverter in the

rated input voltage range

power supply connect to RST of inverter, confirm

the correct grounded then supply power

Confirmed the inverter power matches to the

motor power ,reset the factory value of y00 =5

Select motor parameters, motor parameters set in accordance

with motor nameplate set of parameters, rated power, rated

current, rated voltage, the number of pole pairs, motor speed

Set the appropriate acceleration and deceleration time, the motor

maximum frequency F12, the fundamental frequency F15

Set the keyboard for a

given frequency of F01

Press the keyboard keys

are transferred to run FWD

Shut down power outages, swap

any two-phase motor line

forward running

direction of the motor

Y

Shut down after the motor

parameter tuning

N

21

b11=1

Calculated using plate

b11=2

Static frequency converter

measurement

Press FWD self-tuning start

(motor may be running safety)

The success of self-tuning

Y

Choose

F00Control mode

sensorless

V/F

Control

vector

control

Sensor

vector

control

22

b11=3

Measurement

converter operation

Set the appropriate F09/F10 acceleration

N

and deceleration parameters, F06/F07

torque control parameter

Section IV Test Runing

n

Section V Parameter Function Table

Notice: ★ mean that the factory setting value of the parameter is according to the power and model.The

exact value is referred to the Parameter Function Table.Change limited mean that whether it can be modified

while running.

5-1. Menu Group

Section IV

Code Description / LCD Function Discription Group ID

Monitor Function

S

Group

F Basic Function Group

Section V

A User Function Group Monitor, protection, communication setting

o IO Function Group Analog, digital input, output function

Multi-speed PLC

H

Group

U V/F parameter Group User defined V/Fcurve

P PID Function Group Internal PID parameter setting

E Extend Function Froup

Speed ring function

C

group

b Motor parameter group Motor parameter setting

y System Function Group

Monitor frequency, current and other 16 monitor
objects

Frequency setting, control mode,accelerationtime
and deceleration time

Multi-speed running, PLCrunning

Constant pressure water supply and other functio
setting

Current ring, speed running, PGparameter

Parameter reset, fault query, product information,
parameter protection

Refer

to page

0B

00 25

01

02

03

04

05

06

07

08

09

24

40

52

70

78

79

82

88

93

96

5-2. Monitor function:S00-S15(0x0B00-0x0B0F)

Code Description / LCD Setting Range Unit

S00 Setting Frequency current inverter real setting frequency Hz - N

Real Frequency current inverter real output frequency Hz - N

S01

Motor real Current Valid value of motor actual current A - N

S02

Percentage of Motor

S03

Current

DC Bus Voltage Detection value of DC bus voltage V - N

S04

The Output Voltage The real output voltage V - N

S05

Motor Real Speed Motor real running speed - - N

S06

Under running, the real speed of the motor＝60*the real output frequency *Gain Speed surveillance

/pole of the motor .

Example: the real output frequency50.00Hz, Gain Speed surveillance A35=100.0%, the pole of the

motor b03/b16＝2, the real speed of the motor＝1500rpm.

When stop, based Residual voltage test motor speed, renew speed 500ms.
The real speed ＝60*residual frequency*Gain Speed surveillance / the pole of the motor
Max display of motor real speed 9999rpm.

23

The percentage of actual motor curr ­ent and rated current

24

Factory

Setting

% - N

Change

Limited

Section V Parameter Function Table

Section

V

Section V Parameter Function Table

Total Running Time The total running time for every time hour - N

S07

When the ouptput, the frequency inverter calculated the running time.
Total running time can be cleared up automatically with A33 selecting reboot or continue accumu -

lation after reboot

Total running time of the units can be changed by parameter A34, you can choose hours or days as

the unit

IGBT Temperature ℃

S08

PID Set Point

S09

PID Feedback

S10

Motor Output

S11

Frequency

The output frequency of the motor＝the actual frequency of the motor *A36the regulate of the

motor frequency

Max display of the output frequency 2999.9

Excitation Heft Set

S12

Va l ue

Excitation Heft

S13

Actual Value

Torque Heft Set Value Motor set torque percentage % - N

S14

Torque Heft Actual

S15

Va l ue

Test the temperature of IGBT in the
frequency

PID Adjust run-time values of the
percentage of a given

PID Adjust run-time values of the
percentage of feed back

The percentage of actual output power
of motor

Motor’s set excitation heft percentage % - N

Motor’s actual excitation heft percentage% - N

Motor actual torque hefts percentage % - N

℃ - N

% - N

% - N

% - N

5-3. Basic function Group:F00-F50(0x0000-0x0032)

Code Description / LCD Setting Range Unit

V/Fcontrol 0

F00 Control Mode

Control mode choose, setting 0~2.
0 : V/ Fcontrol

It is not sensitive to motor parameters, can be used as power supply; for motor control, using the
combination of vector control and V / F control strategies, appropriately adjusts motor parameters,
obtain high-performance control effect; suitable for a inverter driving a motor occasions; suitable
for a inverter driving multiple motors occasions; suitable for the inverter as a variable frequency
power supplies.

1 : Sensorless vector control

High-performance speed sensorless vector control; need to set the appropriate electrical parameters
or the motor parameter tuning; truly achieved the decoupled AC motor, so that operational control
of DC motors.

2 : Sensor feedback close loop vector control

Suitable for high precision speed control occasions, need to install PG card and pulse encoder shaft
in the motor or mechanical equipment.

Keyboard Setting

F01

Frequency

Sensorless vector control 1

Sensor feedback close loop
vector control

Lower frequency~upper frequency Hz 50.00 Y

2

Factory

Setting

- 0 N

Change

Limited

The keyboard for a given operating frequency,it can be any frequency between lower frequency and

upper frequency .

F02/F03setting to 0, Involved in setting frequency calculation.

Keyboard setting frequency or
RS485

AI1 the external analog setting 1

Frequency Main Set

F02

Mode

Section V

The main mode of the frequency running frequency:
0 : keyboard setting frequency or RS485 change F01 keyboard setting frequency

Multi-digital voltage terminal effective exchange, change F01keyboard setting value

1 : AI1 the external analog setting

Given the external analog0~10V,-10V~+10V,0~20mA.For detail please read the o group parameter.
2 : AI2 the external analog setting
3 : AI3 the external analog setting

Given the external analog 0~10V, 0~20mA. For detail please read the o group parameter.
4 : Keyboard potentiometer setting

Keyboard potentiometer setting, keyboard potentiometer for a given start and end values of the

corresponding values can be positive role and negative effects. For detail please read the A group

parameter.
5 : Multi-segment digital voltage setting

o36~o46 IO input terminal function set to 11, 12, 13, switch H47~H54 Multi-digital voltage

setting, 100% Corresponding to the maximum frequency .
6 : Digital pulse setting

Digital pulse input frequency Corresponding to the setting frequency, For detail please read the o52

group parameter.

Pulse input terminal and DI8 terminal reset, after using the digital pulse input,o43set to0,Otherwise,

the function settings will take effect, the pulse input on status of o58 can be checked, be limited to

low-speed pulse.

Through o36~o46 IO input teminal set to 14, 15, 16 be configured to switch the source

Auxiliary Setting

F03

Mode Of Frequency

Auxiliary setting mode of frequency set:
0 : keyboard frequency setting frequency or RS485, change F01 kayboard setting frequency

AI2 the external analog setting 2

AI3 the external analog setting 3

Keyboard potentiometer setting 4

Multi-segment digital voltage
setting

Digital Pulse Setting 6

Keyboard setting frequency or
RS485

AI1 the external analog setting 1

AI2 the external analog setting 2

AI3 the external analog setting 3

Keyboard potentiometer
setting

Multi-segment digital voltage
setting

Digital Pulse Set 6

PID regulation mode 7

0

- 0 Y

5

0

- 0 Y

4

5

25

26

Section V Parameter Function Table

Section

V

Section V Parameter Function Table

After multi-digital voltage terminal effective switch, change F01keyboard setting.

1 : AI1 the external analog setting

Given the external analog0~10V,-10V~+10V,0~20mA.For detail please read the o group parameter.

2 : AI2 the external analog setting

Given the external analog 0~10V, 0~20mA.For detail please read the o group parameter.

3 : AI3 the external analog setting

Given the external analog 0~10V, 0~20mA.For detail please read the o group parameter.

4 : Keyboard potentiometer setting

Keyboard potentiometer setting, keyboard potentiometer for a given start and end values of the
corresponding values can be positive role and negative effects. For detail please read the A group
parameter.

5 : Multi-segment digital voltage setting

o36~o46 IO input terminal function set to 11, 12, 13, switch H47~H54 Multi-digital voltage
setting, 100% Corresponding to the maximum frequency .

6 : Digital pulse set

Digital pulse input frequency corresponding to set the frequency, For detail please read o52
parameter.
Pulse input terminal and DI8 terminal reseting, After use digital pulse input, o43set to 0,
Otherwise, the function settings will take effect, can check the pulse input status o58, be limited to
low-speed pulse.

7 : PID regulation mode

The completion of the main to the frequency of common analog feedback loop control. Speed
control accuracy requirements applicable to the general occasions.
The given value can be given through the keyboard can also be given through the analog.
Analog feedback can represent the pressure, flow, temperature.
Details see the P group of parameters.
The completion of the main to the frequency of common analog feedback loop control. Speed
control accuracy requirements applicable to the general occasions.
For a given value can be given through the keyboard can also be given through the analog.
Analog feedback can represent the pressure, flow, temperature.
Details see the P group of parameters.
Through o36~o46 IO input terminal, set to 17, 18, 19 be configured to switch the source for a given
ratio.

The Relationship
Between Main And

F04

Auxiliary Setting
Frequency

The main setting individual
control

The auxiliary setting individual
control

main + auxiliary 2

main -auxiliary 3

(main *auxiliary)/maximum
frequency

0

1

- 0 Y

4

Maximum｛main, auxiliary｝ 5

Minimum｛main, auxiliary｝ 6

Main given and auxiliary given set frequency relations:
Main given value and auxiliary given value can be added up, subtracted, multiplied, maximum,

minimum calculation.

O group parameters can be adjusted to coordinate the main given and auxiliary given proportion, to

meet the requirements of the system fine-tuning and bias.

27

f

f

setting frequency

f

auxiliary

f

main

f

main

F04

f

f

auxiliary

setting frequency

f

max

The relationship between main
give and auxiliary given

t

Main+Auxiliary

f

f

max

Section V

Main-Auxiliary

f

auxiliary

f

main

f

setting frequency

t

f

f

f

max

setting frequency

f

Maximum(Main&Auxiliary)

f

auxiliary

f

main

t

f

f

max

f

setting frequency

(Main*Auxiliary)/The Max Frequency

f

f

f

max

f

setting frequency

Manimum(Main&Auxiliary)

f

main

f

auxiliary

f

auxiliary

f

main

t

t

Keyboard+Rs485/CAN 0

Keyboard+terminal+Rs485/CAN1

F05 Running Control Mode

Rs485/CAN 2

- 0 Y

Terminal control 3

The proportion linkage control 4

Stop and running command control mode：
0 : keyboard+Rs485/CAN Control
1 : keyboard+Terminal+Rs485/CAN Control

control terminal, edge trigger, falling edge of the implementation of the Forward command FWD /

Reverse command REV, rising edge of the implementation of the STOP command
2 : Rs485/CAN Control

Under this function, only free stop funciont is valid under the keyboard control, other operation

control is invalid
3 : Terminal control, Level trigger.

Under this function, only free stop funciont is valid under the keyboard control, other operation

control is invalid

28

Section V Parameter Function Table

Section

V

Section V Parameter Function Table

4 : The proportion linkage control

Select this function, the slave unit would execute the command from the proportion linkage host
unit.
Select this function, can also use keyboard, terminal, RS485 to control the proportion linkage slave
unit to run.

The proportion of linkage running,after stop the proportion linkage slave unit with the keyboard
terminal, Rs485, the slave unit will not run the proportion liknge host unit’s command, it needs once
again to respond to host commands through the keyboard, terminal, RS485, or the proportion linkage
host sends stop command so that slave unit could respond to run commands.

Beeline V/Fcurve 0

F06 V/F Boost Mode

1 bit

10 bit

100 bit

Power of 1.2
V/Fcurve

Power of 1.7 power
V/Fcurve

Power of 2
powerV/Fcurve

Define mode
V/Fcurve

Close Automatic
torque boost

Automatic
torqueboost

VF mode 0 Speed
No Output

VF mode keep 0
speed

1

2

3

4

- 0000 N

0

1

0

1

1 Bit: V/F promote curve

0 Line V/F curve: Suitable for ordinary constant torque load

1 Power of 1.2 V/F curve: Appropriate torque down V/F curve, Suitable for liquid loads

2 Power of 1.7 V/F curve: Appropriate torque down V/F curve, Suitable for liquid loads

3 Power of 2 V/F curve: Torque down V/F curve, It is suitable for fans, pumps, centrifugal load

4 Define mode V/Fcurve: Can be customized appropriate curve according to the actual situation .
10 bit: Auto-torque boost mode

0 Close Automatic torque boost

1 Open automatic torque boost
parameters which affect automatic torque enhance :

Actual value torque component S15

b06/b19 stator resistance

F07 torque enhance value

Automatic torque enhance value = actual value of torque component * stator resistance *torque
enhance value.

100 bit: VF mode 0 speed maintain function

0 VF mode 0 Speed No Output: Output frequency is less than 0.5Hz, stop PWM output to reduce
the switching loss.
1 VF mode keep 0 speed: the output frequency is 0Hz, in accordance with the DC braking current
of starting F26, keep 0 speed.

F07 Torque boost Value 0.0~30.0% % 0.0 Y

Torque Boost Cut-off

F08

Frequency

0.00~Maximum frequency Hz 15.00 Y

Torque increase is mainly used to improve the low-frequency torque characteristics under sensorless

-V / F control mode.
Torque boost is too low, weak low speed motor
Torque boost is too high, motor over-excitation operation, large inverter output current, and low

efficiency.

The setting frequency of the inverter is lower than the frequency of the torque rising,the torque rising

will be valid;over than the setting frequency the torque rising will invalid.

Voltage

motor rated
voltage

Enhance

Section V

voltage

Cut-off frequency

down the torque curve torque boost

Frequency

Basic frequency

Voltage

motor rated
voltage

Enhance

voltage

Cut-off frequency

Constant torque curve torque boost

Frequency

Basic frequency

F09 Accelerate Time 0.0~3200.0 s 10.0 Y

F10 Decelerate Time 0.0~3200.0 s 10.0 Y

F09 Accelerate time: accelerate time from 0Hz to maximum frequency.
F10 Decelerate time: decelerate time from maximum frequency to 0Hz.

Fmax

F10

running time

Percentage Of Output

F11

Voltage

F09

Linear Acceleration

50~110 % 100 Y

The percentage of the actual output voltage and the rated output voltage.
Used to adjust the output voltage,output voltage＝inverter rated output voltage*percentage of output

voltage.

F12 Maximum Frequency 10.00~320.00 Hz 50.00 N

Inverter output maximum frequency allowed is also the setting basis of acceleration / deceleration

time.

This parameter setting, you should consider characteristics of the motor speed and capacity.

F13 Lower Frequency 0.00~Upper frequency Hz 0.00 N

F14 Upper Frequency Lower frequency~Upper frequency Hz 50.00 N

F13 Lower frequency: the lower limit of the output frequency.
F14 Upper frequency: the uppper limit of output frequency.
When the frequency setting command is higher than the upper frequency, the operating frequency

will be the upper frequency;When the frequency setting command below the lower frequency,the
operating frequency is lower frequency. Start the motor that in the status of stopping, the inverter outputs
accelerate starting from 0Hz, accordance with the step 1 acceleration time towards the upper or the
setting frequency to accelerate. when motor Stop, the operating frequency decelerate according to

29

30

Section V Parameter Function Table

Section

V

Section V Parameter Function Table

deceleration time down to 0Hz.

Fmax

upper limit frequency

lower limit frequency

100

％

0

frequency set signal

F15 Basic Frequency 5.00~Maximum frequency Hz 50.00 N

Corresponding to different fundamental frequency of the motor select this function. The basic V / F

characteristic curve is as below.

Vout

Un

base

frequency

maximum
frequency

Fout

F16 Carrier Frequency 1.0~16.0 kHz ★ Y

This function is chiefly used to improve the possible noise and vibration during the operation of
frequency converter. When carrier frequency is higher, the output current has better wave, the torque is
great at lower frequency and the motor produces light noise. So it is very suitable for use in the
applications where great torque is output at low frequency quietly. But in these applications, the damage
to the switches of main components and the heat generated by the inverter are great, the efficiency is
decreased and the output capacity is reduced. At the same time, more serious radio interference is
resulted and special attention must be paid for application where very low EMI is needed, and filter
option can be used if necessary. Another problem for application of high carrier frequency is the increase
of capacitance-leakage current. The protector for leakage current may invalidate function, and over
current is also possibly caused.

When low carrier frequency is applied, the case is almost contrary to the above-mentioned one.

Different motor has different reflection to the carrier frequency. The best carrier frequency is gained
after regulation according to actual conditions. The higher the motor capacity is, the lower the carrier
frequency should be selected.

The company reserves the right to limit maximum carrier frequency as following:

The relation between carrier frequency and Motor Noise, Electric disturbance, Switch dissipation is
expressed as following:

Carrier

Frequency

1.0KHz

8.0KHz

16.0KHz

Motor Noise Electric disturbance Switch dissipation

Big



Small

Small



Big

Small



Big

The relationship of the carrier frequency and power :

Power(kW) 0.4-18.5 22-30 37-55 75-110 132-200 220 以上

Carrier Frequency (Hz) 8.0K 7.0K 4.0K 3.6K 3.0K 2.5K

Note: Carrier frequency is bigger, the temperatuer of the machine is higher.

Carrier Frequency

F17

Adjustment Range

0.0~4.0 kHz 0.0 Y

No automatic
adjustment

1 bit

Carrier Frequency

F18

Adjustment Mode

Section V

automatic adjustment
Mode

automatic adjustment,
Fixed mode

10 bit

automatic adjustment,
random mode

F17 Carrier frequency adjustment range

0.0~4.0kHz, Actual Carrier frequency adjustment range 1.0~16.0kHz
F18 Carrier frequency adjustment Mode

1 Bit: Carrier frequency automatic adjustment mode

0: No automatic adjustment
Carrier frequency according F16 to set .
1: automatic adjustment Mode

The carrier frequency automatically adjusts the model 10 can select random mode and fixed pattern.

10 Bit: Stochastic adjustment mode

0: automatic adjustment, Fixed mode
Load current>80% Carrier frequency =F16-F17
Load current<60% Carrier frequency =F16+F17
1: automatic adjustment, random mode
Load current >80% Carrier frequency = (F16-F17)~F16
Load current <60% Carrier frequency = F16~(F16+F17)

Asynchronous space-vector
PWM

Waveform Generation

F19

Mode

Stepless & subsection
synchronous space vector PWM

two-phase optimization space
vector PWM

PWM wave produce mode
0: Asynchronous space-vector PWM
1: Stepless & subsection synchronous space vector PWM
2: two-phase optimization space vector PWM

S Curve Start Time At

F20

The Acceleration Step

S Curve Stop Time At

F21

The Acceleration Atep

S Curve Start Time At

F22

The Deceleration Step

S Curve Stop Time At

F23

The Deceleration Step

0.0~50.0 % 0.0 Y

0.0~50.0 % 0.0 Y

0.0~50.0 % 0.0 Y

0.0~50.0

1 indicat that the slope of the output frequency from 0 to the max.

0

1

- 00 Y

0

1

0

- 0 N

1

2

% 0.0 Y

31

32

Section V Parameter Function Table

Section

V

Section V Parameter Function Table

2 indicat that the slope of the output frequency at constant segment.
3 indicat that the slope of the output frequency is reduced to 0 from the max.
Such as setting the S curve acceleration and deceleration, acceleration and deceleration time from

0Hz to the maximum frequency is calculated as follows:

Plus acceleration S characteristic time = F09 * F20
Constant extra acceleration S characteristic time = F09-(F09 * F20 + F09 * F21)
Minus acceleration S characteristic time = F09 * F21
Full acceleration time = F09 Acceleration time
Velocity S addition and subtraction characteristic time = F10 * F22
Constant deceleration S characteristics time = F10-(F10 * F22 + F10 * F23)
And reduction rate of S characteristic time = F10 * F23
All deceleration time = F10 deceleration time

Target frequency

F20 F21 F22 F23

Current frequency

V/F Control Slip

F24

Compensation

1 12

3

F09

S curve acceleration&deceleration

slip compensation invalid

slip compensation valid

2

F10

0

1

3

running time

- 0 N

Valid only under V/F control mode.
0 : Slip compensation function is invalid.
1 : Slip compensation function is valid.

Slip compensation value adjusted by the following parameters to ensure stable speed under load

fluctuations and heavy load,

C09 Low Slip Gain
C10 Low Slip switching frequency
C11 High-Speed Slip Gain
Slip C12 high-speed switching frequency

Minimum Running

F25

Frequency

lower limit
frequency

Minimum
frequency

lower limit

frequency

Minimum
frequency

Minimum frequency<lower frequency

0.00~maximum frequency Hz 0.00 N

set frequency

actual frequency

Time

Time

Minimum

frequency

lower limit

frequency

Minimum
frequency

lower limit
frequency

Minimum frequency>lower frequency

set frequency

actual frequency

Time

Time

The set frequency lower than the minimum running frequency, the converter will stop, that is, when

the set frequency is less than the minimum running frequency, are determined that the set frequency is 0.

33

Minimum running frequency" and "lower frequency" relationship is as follows.

DC Braking Current

F26

When Starting

Braking Time When

F27

Starting

0~135 % 100 Y

0.0~60.0 s 0.0 Y

When frequency Inverter starting, the first injection of DC current, the current size is determined by
starting to set when the DC braking current and braking time, braking time from the start to set.

Value is based on inverter rated current as the benchmark, that is inverter rated current corresponds
to 100%. During setting process, be sure to gradually increase, until adequate braking torque, and can
not exceed the motor rated current.

output

frequency

start up braking

Section V

RUN

STOP

Stop When The DC

F28

Braking Current

Stop And Braking

F29

Wait Time

ON

start up braking

0~135 % 100 Y

0.0~60.0 s 0.0

F30 Brake Time Stop 0.0~60.0 s 0.0

Stop And Brake

F31

Starting Frequency

0.00~most frequency Hz 0.00 Y

time

Y

Y

Inverter slowing down to stop braking start frequency, stop the output PWM waveform to begin
injection of DC current, the current size by the shutdown of DC braking current setting, braking time,
braking time set by the downtime.

Value is based on inverter rated current as the benchmark, that is inverter rated current corresponds
to 100%. Setting process, be sure to gradually increase from a small, until adequate braking torque, and
can not exceed the motor rated current.

setting

frequency

output

frequency

braking

frequency

RUN

STOP

ON

Stop braking (RUN

stop brake wait time

stop braking time

OFF

→

STOP)

time

time

34

Section V Parameter Function Table

Section

V

n

n

Section V Parameter Function Table

setting

frequency

output

frequency

braking

frequency

forward
reverse
command

setting

frequency

braking

frequency

output

frequency

braking

frequency

RUN
STOP

FOR

stop braking (forward and reverse rotate)

stop braking (run state)

F32 Stop Setting Mode

stop braking time

stop brake wait time

REV

stop brake wait time

stop braking time

ON

Deceleration stop 0

Free stop 1

time

time
setting
frequency

time

time

- 0 N

When the frequency inverter receives the "stop" command, it will set the parameters accordingly to

this parameter to set the motor stop mode.

0 : deceleration to stop

Mode converter according to parameters set by the deceleration time to set the deceleration mode
to slow down to the lowest frequencies to stop.

1 : Free stop mode

Inverter receive "stop" command immediately stop output, according to the load inertia, motor
free-run to stop.

F33 Jog Acceleration Time 0.0~3200.0 s 1.0 N

F34 Jog Deceleration Time 0.0~3200.0 s 1.0 N

F35 Jog Mode Setting

Jog direction: forward 0

- 000 N

Jog direction: reverse 1

1 bit

Jog direction:
direction determined

2
by the main terminal

Jog end mode: Stop
Running

10 bit

Jog end mode:reset to
the former state before

0

1
jog

35

Jog end and acceleratio
deceleration time: reset
to the set acceleration

0
and deceleration time
before jog

100 bit

Jog end and acceleratio
deceleration time:save
the set acceleration and

1
deceleration time before
jog

F36 Jog Frequency Setting Lower frequency ~upper frequency Hz 6.00 Y

Section V

Fmax

F33

Linear Acceleration

F34

running time

Jog acceleration/deceleration time configuration defines the same section of acceleration / decele -

ration time.

The direction of jog is set by the unit bit of F35,when the Jog command does not contain the dire ­ction of jog, the direction of job will run as to the unit bit designated by F35. It is set to 2, the direction
of jog is run by the terminal or current direction.

The running status after jogging is identified by F35.

Whether jog acceleration/deceleration time is maintained through the confirmation on hundred bit
of F35 after jogging

F37 Skip Frequency1Limit 0.00~Maximum frequency Hz 0.00 Y

F38 Skip Frequency1Upper 0.00~Maximum frequency Hz 0.00 Y

F39 Skip Frequency2Limit 0.00~Maximum frequency Hz 0.00 Y

F40 Skip Frequency2Upper 0.00~Maximum frequency Hz 0.00 Y

F41 Skip Frequency3Limit 0.00~Maximum frequency Hz 0.00 Y

F42 Skip Frequency3Upper 0.00~Maximum frequency Hz 0.00 Y

During running, to skip resonance produced by the immanent resonance point in the machine sys -

tems, skip mode can do this.

At most three resonance points could be set to skip.

output frequency

upper skip frequency 1

lower skip frequency 1

upper skip frequency 2

lower skip frequency 2

skip frequency 1

skip frequency 2

skip frequency 3

upper skip frequency 3

lower skip frequency 3

frequency setting signal

36

Section V Parameter Function Table

Section

V

d

d

Upper skip frequency and lower skip frequency define skip frequency range.

In the acceleration and deceleration process, inverter output frequency can normally through skip

frequency area.

F43 Preset Frequency 0.00~Max frequency Hz 0.00 Y

Preset Frequency

F44

Wor king Ti me

0.0~60.0 s 0.0 Y

After inverter startup, it firstly run with preset frequency, running time is preset frequency time,then

it will run with given frequency. Jog run will not be effective by preset frequency.

Direction command:

F45

Motor Running
Direction

forward command
FWD let motor
forward running

1 bit

Direction command:
forward command
FWD let motor
reverse running

Command prior:
terminal/keyboard

10 bit

Prior command:
Analog given positive

0

1

- 0100 N

0

1

and negative values

100 bit

Reverse allow:
reverse forbidden

Reverse allow:
reverse allow

0

1

1 : Bit: used to change the direction of motor running

0: Forward command FWD is to let motor forward running.
1: Forward command FWD is to let motor reverse running.

10 : Motor forward reverse running can be controled by the keyboard potentiometer and analog input

input positive or negative value.

0: Prior command:terminal / keyboard, set frequency can be negative value, but running direction
decided by terminal and keyboard command.
1: Prior command: positive or negative value of analog input, setting frequency positive value let
motor forward running, seting negative value let motor reverse running.

100:motor reverse allow. For some producing equipment, the reverse may lead to damage to the

equipment, so this feature can be used to prevent motor reverse, Inverter default forbidden reverse.
When the motor running direction opposes to equipment required direction, you can exchange the
wiring of any two inverter output terminals to let equipment forward running direction is consistent
with motor running.

0: reverse forbidden
1: reverse allow

F46 Pass 0 Stopping Time 0.0~60.0s s 0 N

Setting this parameter to achieve the motor forward to reverse (or from reverse running to forward),

the waiting time of motor speed being zero

Section V Parameter Function Table

output

frequency

F47

running time

Frequency Multiple

F47

Setting

0 : Set frequency display accuracy 0.01Hz

Section V

With this accuracy, F12 Maximum frequency setting range 10.00~320.00Hz.

*1 0

*10 1

- 0 N

1 : Set frequency display accuracy 0.1Hz

with this accuracy, F12 Maximum frequency setting range 100.0~800.0Hz.
After setting this parameter, there must be reset F12 maximun frequency.

Acceleration And

F48

Deceleration
Configuration Word

N adjustment of
acceleration time

AI1 adjustment of the
external analog giving

AI2 adjustment of the
external analog giving

1 bit

AI3 adjustment of the
external analog giving

Adjustment of keyboar
potentiometer giving

- 0000 N

0

1

2

3

4

Adjustment of Multi
steps digital voltage

5

giving

10 bit

N adjustment of
decceleration time

AI1 adjustment of the
external analog giving

AI2 adjustment of the
external analog giving

AI3 adjustment of the
external analog giving

Adjustment of keyboar
potentiometer giving

0

1

2

3

4

Adjustment of Multi
steps digital voltage

5

giving

Acceleration time:*s 0

100 bit

1000 bit

Acceleration time:*min

Acceleration time:*h

Acceleration time:*day

Deceleration time:*s 0

1

2

3

37

38

Section V Parameter Function Table

Section

V

:

Section V Parameter Function Table

Deceleration time:*min 1

Deceleration time:*h 2

Deceleration time:*day 3

1 bit: Acceleration time ajustment mode

0 No Adjustment Of Acceleration Time No adjustment

AI1 Adjustment Of The External

1

Analog Giving

AI2 Adjustment Of The External

2

Analog Giving

AI3 Adjustment Of The External

3

Analog Giving

Adjustment Of Keyboard

4

Potentiometer Giving

Adjustment Of Multi Steps Digital

5

Voltage Giving

10 bit: Deceleration time ajustment mode

0 No Adjustment Of Acceleration Time No adjustment

AI1 Adjustment Of The External

1

Analog Giving

AI2 Adjustment Of The External

2

Analog Giving

AI3 Adjustment Of The External

3

Analog Giving

Adjustment Of Keyboard

4

Potentiometer Giving

Adjustment Of Multi Steps Digital

5

Voltage

100, 1000 bit: The unit of Acc. and Dec time when program running on 0 step speed

Acc. and Dec. time 1000 bit 100 bit

*s

*Min

*H

*Day

Running Configuration

F49

Wor d

0

1

2

3

1 bit

10 bit

Actual Acc. time=Acc. time*AI1 giving percentage

Actual Acc. time = Acc. time*AI2 giving percentage

Actual Acc. time = Acc. time*AI3 giving percentage

Actual Acc.time = Acc. time*keyboard potentiometer

giving percentage

Actual Acc.time=Acc.time*Multi steps digital voltage

giving percentage

Actual Acc.time =Dec. time*AI1 giving percentage

Actual Acc.time = Dec. time *AI2 giving percentage

Actual Acc.time = Dec. time *AI3 giving percentage

Actual Acc.time = Dec. time*keyboard potentiometer

giving percentage

Actual Acc.time=Dec.time*Multi steps digital voltage

giving percentage

Range(e.g. F09, F10=3200.0)

3200.0s

3200.0 Min

3200.0 h

3200.0 Day

Running direction:
forward

Running direction:
reverse

Running time: *S 0

Running time: *Min 1

Running time: *H 2

Running time: *Day 3

0

1

- 0000 N

Unit adjustment of actual running time.It is only valid on program running.
1 bit: Program running on multi-speed running period, Set bit to running direction of “0”step speed.

Running driection Setting value

Forward 0

Reverse 1

When running control mode F05＝0/1/2, control direction of “0” step speed.

When running control mode F05＝3, Setting the value and terminal FWD / REV jointly decide the

direction of 0 step speed, FWD priority.

FWD=1running

direction

Section V

10 bit: unit of time running when on “0” step speed.

F50

This parameter describes the minimum output voltage percentage of energy-saving operation. In the
constant speed operation, the inverter can be automatically calculated the best output voltage by the load
conditions.In the process of acceleration and deceleration is not to make such calculations.

Power-saving function is by lowering the output voltage and improve power factor to achieve the
purpose of saving energy, this parameter determines the minimum value of reducing of output
voltage;This parameter is set to 100%, then energy-saving function will take off.

When energy-saving function in effect, Actual output voltage value of inverter= The inverter rated
output voltage*The percentage of output voltage*output voltage percentage of energy saving operation.

output voltatge (V)

FWD REV 0

REW FWD 1

Running time 10 bit range(e.g. H18~H25=3200.0)

*S

*Min

*H

*Day

Energy Saving
Running Percentage

100%

75%

REV=1running

direction

0

1

2

3

30~100 % 100 N

frequency (Hz)

Setting value

3200.0s

3200.0Min

3200.0H

3200.0 Day

5-4. User Function Group:A00-A55(0x0100-0x0137)

Factory

Code Description / LCD Setting Range Unit

A00

Monitor 1

A01

Monitor 2

A02

Monitor 3

Code Keyboard display

S Monitor Function Group

Parameter group N: Parameter group N

X1000/X100 X10/ bit

00~0B 0~63(0x00~0x3F)

Paramete
r group N

0B

Function

spec

S 0~16 (0x00~0x10)

Parameter N(16

Hexadecimal Input)

-

-

-

Setting

0B00
0B01
0B02

Change
Limited

Y
Y
Y

39

40

Section V Parameter Function Table

Section

V

Section V Parameter Function Table

F Basic Function Group 00 F 0~60 (0x00~0x3C)

A User Function Group

o IO Function Group

H Multi-step Speed PLC Group

U V/F Curve Group

P PID Function Group

E Extend Function Group

C Speed Loop Parameter Group

b Motor Parameter Group

y System Function Group

01

02

03

04

05

06

07

08

09

A 0~56 (0x00~0x38)

o 0~61 (0x00~0x3D)

H 0~56 (0x00~0x38)

U 0~16 (0x00~0x10)

P 0~13 (0x00~0x0D)

E 0~14 (0x00~0x0E)

C 0~32 (0x00~0x20)

b 0~23 (0x00~0x17)

y 0~18 (0x00~0x12)

That parameter N. should be 16 hex input.
Monitor1 will be valid when first power on, and which decide keyboard display content.
Such as:monitor 1 S01 actual frequency, A00=0x0B01.
Monitor 2 o57 DI1~4 terminal status, A01=0x0239.
Monitor 3 H55 multi-steps speed status, A02=0x0337.

A03

A04

Over /Less Voltage
Stall Protection

Overvoltage Stall
Protection Voltage

N 0

Y 1

- 1 Y

110%~140%( Standard bus voltage) % 120 Y

0 : This function invalid
1 : This function valid

When the inverter deceleration, as the motor load inertia, motor will produce feedback voltage to
inverter inside, which will increase DC bus voltage and surpass max voltage. When you choose Over
/less voltage stall protection and it is valid, Inverter detects DC side voltage, if the voltage is too high,
the inverter to stop deceleration (the output frequency remains unchanged), until the DC side voltage is
below the set value, the inverter will re-implement the deceleration

With braking models and external braking resistor, this function should be set to “0”.

DC voltage

time

output frequency

Security Type 1

General Type 2

A07 Hysteresis voltage 0~10% % 2 Y

Dynamic Braking

A08

Voltage

110%~140%( Standard bus voltage) % 130 Y

0 : Invalid
1 : Security Type

Only in the inverter deceleration process,and detected high-voltageDCbus exceeds a predetermined
value, the dynamic braking will be implemented

2 : general Type

under any state, when the inverter detected high-voltage DC bus exceeds a predetermined value, the

Section V

dynamic braking will be implemented.

When the inverter is running on emergency deceleration state or load great fluctuation, it may
appear over-voltage or over-current. This phenomenon is relatively prone to happen when the motor load
inertia is heavy.When inverterThe inverter internal DC bus detected voltage exceeds a certain value, the
output brake signal through an external braking resistor implement energy-braking function. Users can
select inverter models with a braking function to apply this feature.

A09 Less Voltage Level 60%~75%(Standard DC bus voltage) % 70 Y

The definition of allowed the lower limit voltage of normal working inverter DC side .For some
low power occasions, inverter less voltage value can be appropriately put down in order to ensure the
inverter normal working..

Under normal condition, keeping default setting.

Power-down Tracking

A10

Options

N 0

Power-off tracking mode 1

- 0 Y

Startup tracking mode 2

Power-down tTracking

A11

Time

input
power

motor
rotate
speed

power down

A11

0.0~20.0 s 0.0 Y

power frequency

control

frequency conversion

motor
rotate

speed

speed search

time

Invalid 0

A05 Auto Stablize Voltage

Valid 1

- 0 Y

Valid, usless for deceleration 2

CPU automatically detect the inverter DC bus voltage and to make real-time optimized processing,
when the grid voltage fluctuate, the output voltage fluctuation is very small,the V / F curve characteristic
has always been close to setting state of rated input voltage..
0 : function inalid.
1 : function Valid.
2 : function Valid, but useless for deceleration.

A06 Dynamic Braking option

Invalid 0

41

- 0 Y

output

frequency

power down track state

This parameter is used to select the inverter tracking mode.

output

frequency

start track state

0 : N speed tracking means to start tracking from 0 Hz.
1 : power-down tracking

When the inverter instantaneous power off and re-start, the motor will continue running with
current speed and direction.
If the power off time is longer than A11 set time, the inverter will not re-start power on again.

2 : Startup tracking means that when power on, inverter will first inspect motor direction and speed,

and then driving motor with current speed and direction.

42

Section V Parameter Function Table

Section

V

Section V Parameter Function Table

Set startup tracking function, power off tracking function is still valid.

Power Down Frequency

A12

Drop Point

Power Down Frequency

A13

Drop Time

Correctly setting this parameter can let inverter does not less voltage stop in case of instantaneous
power off.

When the DC bus voltage drop to frequency drop point A12 set, inverter will decelerate according
to deceleration time A13 set and stop outputting power to load. Meanwhile, inverter will use load
feedback energy to compensate DC bus voltage dropping and keep inverter working in short time.

Power down frequency drop time actually is deceleration time of frequency dropping after power
off.

If this value set is too large, the load feedback energy is small, then inverter can not compensate for
voltage dropping in DC.

if this value set is too small and there is large energy feedback from load, the excessive energy
compensation may cause inverter over-voltage fault.

Set A12 100% to cancel power off frequency dropping function.

A14 Current Limit

A15 Limit Fall Time 0.1~3200.0 s 10.0 Y

Limit Deceleration

A16

Protection Point

Limit Fix-speed

A17

Protection Point

Series Current limitaiton% Corresponding parameter

F

G

M、T、Z

H

Current limitation function can effectively restrain over-current caused by motor load fluctuation in
the process of acceleration and deceleration or constant speed operation.

This function will be good effect for V/F control mode.

Under protection of current lost- speed state, the motor speed will drop. so it is not adapted by
systme which is not allowed to automatically drop speed.

In operation process, when the motor current surpass value A16 set, motor will decelerate
according to deceleration time A15 set until current below value A16 set.

In operation process, when the motor surpass value A17 set, motor will run with this speed until
current below value A17 set.

Deceleration current limitation is prior of constant speed limitation.

Output Phase Lose

A18

Protection

65~100%(standard DC bus voltage) % 75 Y

0.1~3200.0 s 5.0 Y

N 0

Y 1

10~250 % ★ Y

10~250 % ★ Y

120 A17

130 A16

150 A17

170 A16

170 A17

190 A16

250 A17

270 A16

N protection of phase lost 0

Warning and constant running 1

- 0 Y

- 0 Y

Warning and deceleration 2

Warning and free stopping 3

Grade Of Phase Lose

A19

Protection

When ratio of unbalance 3phase output surpass A19 Grade of phase lose protection, the inverter

output phase lose protection i will action, and the system display fault PH-O.

Output frequency less than 2.00Hz, there is N output phase lose protection.
Phase lost protection grade=max current difference between phases, which will be according to

load condition.

Over Torque Inspected

A20

Action

Section V

A21 Over Torque Grade 10~250 % ★ Y

Over Torque Inspection

A22

Time

Motor output current surpass value A21 set, Over torque inspection will be force and the system

will show OL2 fault.

Series Over torque inspection class Parameter

F 130 A21

G 170 A21

M、T、Z 190 A21

H 270 A21

Electronic Thermal

A23

Relay Protection
Selection

Electronic Thermal

A24

Protection Grade

This function is to protect motor overheating when motor does not use thermal relay. Inverter using
some parameters to calculate motor temperature rise, at the same time to determine whether the use of
current caused motor overheat. When you choose electronic thermal protection function, the drive output
is shutdown after overheating detected also shows information of protection.
0 : No selecting this function
1 : Select this function.

Series electronic Thermal Protection Level Parameters

F 120 A24

G 150 A24

M、T、Z 170 A24

H 250 A24

A24 set the electronic thermal protection level. When the current is the rated motor current

multipleis the parameter, the drive in 1 minute protects, thermal protection within one minute that means

the actual current is A24 times of the rated current.

10~100 % 30 Y

N torque inspection 0

Warning and running 1

Warning and decelerating stop 2

Warning and free stopping 3

0.0~60.0 s 0.1 Y

N 0

Y 1

120~250 % ★ Y

- 0 Y

- 1 Y

43

44

Section V Parameter Function Table

Section

V

Section V Parameter Function Table

protect time

20min

5min

1min

0.2s

％

A24

Ia

A25 Fault Reset Times 0~10 - 0 Y

In the inverter operation process, Over Current expressed by OC、Over Voltage by OU, inverter can

automatically recover and run with state of preceding fault. Recovering times will be according to this
parameter. It can set 10 times at most. When this parameter is set “0”, inverter will not automatically
recover after meeting fault. But if relay in DC main circuit meet fault “MCC” or less votage “LU” fault,
inverter will automatically recover without limitation.

Restarting from fault and normally running over 36s, inverter will automatically recover fault reset

times preset.

Restarting from fault and normally running over 36s, inverter will automatically recover to display

monitor parameter.

After 10 s of meeting fault, inverter will not recover fault reset function.

A26 Fault Reset Time 0.5~20.0 s 1.0 Y

Setting interval of fault reset time. When inverter met fault and stopped outputting, and when it
inspected without fault time is longer than fault reset time, Inverter will automatically implement fault
reset.

Fan Startup

A27

Temperature

0.0~60.0 ℃ 0.0 Y

Set the fan start temperature.When the actual temperature of theS08is higher than the set temperature
the fan starts.

To avoid the the fan frequently starts and stops , the fan stop temperature = A27 fan start temperature

-1.0 .℃

This Inverter

A28

Communication Address

1~128 - 8 Y

This Inverter communication address: it is the only code to differentiate from other inverters.

Setting range “1~127” is slave inverter address, that can receive command and send out this
inverter state. Seeing attachment 1 for detailed specification.

The proportion of linkage function:

The proportion of linkage host inverter:

This inverter communcaiton address=128,

Communication interface A is set as host inverter communication interface for proportion of
linkage.

Communication interface B can be treated as keyboard interface or “PC” Host Computer Interface.

The proportion of linkage slave inverter:

This inverter communication address =1~127,

Communication interface A and B both can be set as communication interface of slave inverter for
the proportion of linkage.

Seeing appendix 2 for detailed specification.

A29 Baud Rate

Baud rate is 1200 0

- 4 Y

Baud rate is 2400 1

Baud rate is 4800 2

Baud rate is 9600 3

Baud rate is 19200 4

Baud rate is 38400 5

The baud rate of communication port A can be set accordingly.
The baud rate of communication port B is fixed 19200bps.

8, N, 1 for RTU 0

8, N, 2 for RTU 1

A30 Communication Format

Section V

Seeing attachment for detailed specification.

8, E, 1 for RTU

8, O, 1 for RTU 3

8, E, 2 for RTU

8, O, 2 for RTU

N warning for communication
fault

A31

Communications
Troubleshooting

Warning and running 1

Warning and decelerating stop 2

2

- 0 Y

4

5

0

- 0 Y

Warning and free stopping 3

A32 Delay Inspection Time

0: N inspection

1~250: late inpsection

s 10 Y

When communication time between interface A or B surpassed A32 delayt inspection time, the

system will warn according to A31 setting.

After power on, interface without communication will not implement warning.

Total Running Time

A33

Setting

Auto clear to zero after power
on

Continue to accumulate
running time after power on

0

- 1 Y

1

To set whether the time of inverer running accumulating or not.
0 : Auto clear to 0 after power on.
1 : Continue to accumulate running time after power on.

Unit Of Total Running

A34

Time

hour 0

Day 1

- 0 Y

The set for unit of accumulation running time, only for display of running time.
0 : unit /hour display range 0~3200.0 hour.
1 : unit/day display range 0~3200.0 day.

Motor Output Speed

A35

Adjustment

0.1~1000.0 % 100.0 Y

Using for displaying adjustment of motor actual running speed.SeeingA00~A02 monitor options: 6:
motor actual running speed.

Setting 100%, corresponding display unit : rpm.

The max speed of displaying after adjustment is 9999.

Adjustment Of Motor

A36

Output Power

0.1~1000.0 % 100.0 Y

Used for displaying motor ouput power of adjustment. Seeing A00~A02 monitor options: 11 :motor
output power.

45

46

Section V Parameter Function Table

Section

V

Section V Parameter Function Table

Setting 100%, corresponding display unit:%.
The max ouput power of displaying after adjustment is 2999.9.

Keyboard Lock

A37

Function Options

0~0FF

Key SET+ESC in Keyboard can activate and cancel keyboard lock function.

To lock which key will be decided by corresponding parameter :

22222222
76543210

4567

0123

FWD
STOP
PRG
SET
ESC

MF1
MF2

Potentiometer

Set 0~10 bit Keyboard locked state

0 Unlock FWD key

1 Lock FWD key

0 Unlock STOP key

1 Lock STOP key

0 Unlock PRG key

1 Lock PRG key

0 unlock SET key

1 Lock SET key

0 Unlock ESC key

1 Lock ESC key

0 Unlock MF1 key

1 Lock MF1 key

0 Unlock MF2 key

1 Lock MF2 key

0 Unlock potentiometer

1 Lock potentiometer

Power down to save

1 bit

Power down to clear
saving

saving after stopping

Stop command to

10 bit

clear saving

Cleared at the end of
stopping

0

0

A38

0

1

2

3

4

5

6

7

UP/DN Control

One-direction

100 bit

adjustment

Double-direction
adjustment

1000 bit

Invalide adjustment

Valide adjustment

1

1

2

- 0000

0

1

0

1

- 0FF

1 bit:

UP/DN control saving state after power down

0: power down to save

Y

1: power down to clear

10 bit:

UP/DN control saving after stopping
0: Keeping afer stopping
1: Stop command to clear saving
2: Cleared at the end of stopping

100 bit:

UP/DN control direction of adjustment.
0: one direction adjustment, it is one direction adjustment within 0~max frequency range.
1: double direction adjusment, it is FEW and REW adjustment within 0~max frequency range.

1000 bit:

UP/DN control validity of adjustment.
0: UP/DN invalid ajustment
1 : UP/DN valid adjustment

Section V

A39

UP/DN Time

Y

1 bit:

UP acceleration mode

1 bit

10 bit

100 bit

1000 bit

UP fix speed

UP fix times

DN fix speed

DN

UP N adjustmentof
speed ratio
AI1 adjustment of the
external analog giving

AI2 adjustment of the
external analog giving

AI3 adjustment of the
external analog giving

adjustment of
Potentiometer giving

Adjustment of multi

-steps digital voltage

DN N adjustmentof
speed ratio
AI1 adjustment of the
external analog giving

AI2 adjustment of the
external analog giving

AI3 adjustment of the
external analog giving

adjustment of
Potentiometer giving

Adjustment of multi

-steps digital voltage

0

1

0

1

fix times

0

1

2

3

4

- 0000

5

0

1

2

3

4

5

N

0: fix speed acceleration, according to A41 fix speed: To increase frequency every 200ms.
1: fix times acceleration, according to fix times: To increase frequency every triggering.

10 bit:

DN deceleration mode
0: fix speed deceleration, according to A42 fix speed: To reduce frequency every 200ms.
1: fix times deceleration, according to A42 fix times: To reduce frequency every triggering.

100 bit:

UP adjustment mode of adjusting speed ratio

47

48

Section V Parameter Function Table

Section

V

Section V Parameter Function Table

UP N Adjustment Of

0

Speed Ratio
AI1 Adjustment Of The

1

External Analog Giving

AI2 Adjustment Of The

2

External Analog Giving

AI3 Adjustment Of The

3

External Analog Giving

Adjustment Of

4

Potentiometer Giving

Adjustment Of Multi-steps

5

Digital Voltage

1000 bit:

DN adjustment mode of adjusting speed ratio

N Adjustment Of

0

Acceleration Time

AI1 Adjustment Of The

1

External Analog Giving

AI2 Adjustment Of The

2

External Analog Giving

AI3 Adjustment Of The

3

External Analog Giving

Adjustment Of

4

Potentiometer Giving

Adjustment Of Multi-steps

5

A40

A41

A42

A43
A44

Digital Voltage

UP/DN Adjustment
Va l ue

Frequency after adjustment＝set frequency+UP/DN adjustment value.

UP Adjustment Ratio

Fix speed: To increase frequency every 200ms.
Fix times: To increase frequency every triggering.

DN Adjustment Ratio

Fix speed: To reduce frequency every 200ms.
Fix times: To reduce frequency every triggering.

The Definition Of
Multifunction Keys
MF1 And MF2

0.01~20.00 Hz 0.01 Y

0.01~20.00 Hz 0.01 Y

N adjustment

Actual

UP adjustment ratio

Actua

UP adjustment ratio

Actual

UP adjustment ratio

Actual

UP adjustment ratio

potentiometer

Actual

UP adjustment ratio

multi-steps digital voltage

N adjustment

Actual

DN adjustment ratio

Actual

DN adjustment ratio

Actual

DN adjustment ratio

Actual

DN adjustment ratio

A42*potentiometer

Actual

DN adjustment ratio

A42*multi-steps digital voltge.

-300.00~300.00 - 0.00 N

MF is defined as adding
function key

MF is definded as reducing
function key

MF is defined as free stopping
key

MF is defined as FWD running
key

MF is defined as REV running
key

MF is defined as forward JOG
function key.

= percentage given by A41*AI1

= percentage given by A41*AI2

= percentage given by A41*AI3

= percentage given by A41*

=percentage given by A41*

=percentage given by A42*AI1

=percentage given by A42*AI2

=percentage given by A42*AI3.

=percentage given by

=percentage given by

-

0

1

2

3

4

5

0

-

1

MF is defined as reverse JOG
function key.

MF is defined as JOG function
key.

MF is defined as UP function key 8

MF is defined as Down function
key.

UP / DN adjusted value reset 10

keyboard potentiometer
setting value resey

The user defined keyboard can define MF key functions.

Y
Y

0 : MF is defined as adding function key:

Section V

Under monitor menu, adding function key MF can adding revise frequency F01 set.
Under parameter choosing menu, adding function key MF can adjust parameter choice.
Under parameter revising menu, adding function key MF can adjust parameter value.

1 : MF is defined as reducing function key:

Under monitor menu, reducing function key MFcan reducing revise frequency F01 set
Under parameter choosing menu, reducing function key MF can adjust parameter choice.
Under parameter revising menu, reducing function key MF can adjust parameter value.

2 : MF is defined as free stopping key:

MF key is valid under monitor menu and select parameter menu, inverter will be free stopping. After
free stop, no start command, 1 S later, allow running again..

3 : MF is defined as FWD running key:

Pressing MF key is valid under monitor menu and parameter choosing menu, inverter will be
forward running.

4 : MF is defined as REV running key:

Pressing MF key is valid under monitor menu and parameter choosing menu, inverter will be reverse
running.

5 : MF is defined as forward JOG function key:

Pressing MF key is valid under monitor menu and parameter choosing menu, inverter will be
forward JOG running.

6 : MF is defined as reverse JOG function key:

Pressing MF key is valid under monitor menu and parameter choosing menu, inverter will be reverse
JOG running.

7 : MF is defined as JOG function key:

Pressing MF key is valid under monitor menu and parameter choosing menu, inverter will be JOG
running. Running direction decided by F35 bit setting and terminal state.

8 : MF is defined as UP function key:

Pressing MF is always valid, inverter will be UP control, control parameter decided by A38~A42.

9 : MF is defined as Down function key:

Pressing MF is always valid, inverter will be DOWN control, control parameter decided by
A38~A42.

10：MF is defined as the UP / DN adjusted value resetA40 UP / DN adjusted value reset, level-triggered.
11 : MF is defined as the setting value of potentiometer on the keyboard A47 keyboard potentiometer
setting is reset, level-triggered

Keyboard

A45

Potentiometer X1

The start point of value keyboard potentiometer set.

A46 Keyboard 0~100.0

0~100.0

11

6

7

9

0.0 Y

%

100.0 Y

%

49

50

Section V Parameter Function Table

Section

V

Section V Parameter Function Table

PotentiometerX2

The end point of value keyboard potentiometer set.

The Value Of Keyboard

A47

Potentiometer Set

0.0~100.00 % -

Displaying value potentiometer set, which can be revised by potentiometer under monitor menu.
Value potentiometer set can be regarded as analog of frequency giving , set value = max frequency

*keyboard potentiometer set value.

Potentionmeter set value can be regarded as value of PID giving,value of PID giving=keybaord

potentiometer set value.

Keyboard Potentiometer

A48

X1 Corresponding Value

-100.0~100.0 % 0.00 Y
Y1

Keyboard Potentiometer

A49

X2 Corresponding Value

-100.0~100.0 % 100.00 Y
Y2

End point
corresponding

value

Start point
corresponding
value

start point

end point

1 bit

End point
corresponding
value

Start point
corresponding
value

Saving after power
down

Cleared after power
down

start point

0

1

end point

Saving after stoppoing 0

Keyboad

A50

Potentiometer Control

100 bit

1000 bit

Clear saving after

10 bit

stopping command

Clear saving at end of
stopping

Reserved

Reserved

0000 Y

-

1

2

1 bit: Saving state of potentiometer after power down.

0: Saving after power down.
1: Clearing saving after power down.

10 bit: keeping potentiometer set after stopping.

keeping after stopping

0:
1: To clear saving after stop command.
2: To cear saving at end of stopping.

Temperature

A51

Adjustment Of Motor

0.0~200.0 % 100.0 N

Being used to revise displaying of A54 motor temperature.

Over-heat Temperature

A52

Of Motor

0.0~300.0 ℃ 120.0 N

51

N reaction for motor over-heat 0

Reaction For Motor

A53

Y

Over-heat

Warning and runing 1

Warning and deceleration
stopping

2

- 0

Y

Warning and free stopping 3

When the displaying value of motor temperature A5 surpassed value A52, inverter will warn and

react according to reaction for motor over-heat A53 set.

Display Of Motor

A54

Temperature

-50.0~300.0 ℃ - N

Shows the motor temperature or temperature at other point.

Control card PT100 plug should plug into the optional PT100 thermocouple devices
Three lines PT100

Section V

Proportion Of Linkage

A55

Ratio

In application of proportion of linkage, A55 setting is multiply ratio of that when slave inverter

received setting frequency command from host inverter.

Setting this inverter as one slave inverter of system for proportion of linkage.
Frequency Keyboard F01 set＝proportion of linkage ratio* frequency S00 set by host inverter

5-5. IO function group:o00-o68(0x0200-0x0244)

Code Description / LCD Setting Range Unit

o00

o01

o02

o03

o04 AI3

o05 AI3

o06

o07

o08

o09

o10

o11

X1 0~100.0

AI 1 Input

X2 0~100.0

AI 1 Input

AI2 Input

AI2 Input

AI 1 Input

X1 0~100.0

X2 0~100.0

X1 0~100.0

Input

X2 0~100.0

Input

X1

Corresponding Value Y1

X2

AI 1 Input

Corresponding Value Y2

X1

AI 2 Input

Corresponding Value Y1

X2

AI 2 Input

Corresponding Value Y2

X1

AI 3 Input

Corresponding Value Y1

X2

AI 3 Input

Corresponding Value Y2

Under the situation Max frequency＝50.00hz:

0.10~10.00 - 1.00 Y

Factory

Change

Setting

Limited

0.0 Y

%

100.0 Y

%

0.0 Y

%

100.0 Y

%

0.0 Y

%

100.0 Y

%

-100.0~100.0 %

-100.0~100.0 %

-100.0~100.0 %

-100.0~100.0 %

-100.0~100.0 %

-100.0~100.0 %

0.0 Y

100.0 Y

0.0 Y

100.0 Y

0.0 Y

100.0 Y

52

Section V Parameter Function Table

Section

V

Section V Parameter Function Table

y

Y2=100%

Y1=0%

AI1,AI2,AI3

X1=0%,Y1＝0% potentiometer 0V corresponding set frequency:f=Max frequency*Y1=0.00Hz

(X1,Y1)

X1=0%

X2=100%

x

X2=100%,Y2＝100% potentiometer10Vcorresponding set frequency:f=Maxfrequency*Y2=50.00Hz

y

100%

(

Y2=50%

Y1=0%

AI1,AI2,AI3

X1=20%, Y1＝0% potentiometer 2V corresponding set frequency: f=Max frequency*Y1=0.00Hz

X2,Y2)

X1=20%

(X1,Y1)

X2=50%

80%
10V

100%

x

X2=50%, Y2＝50% potentiometer 5V corresponding set frequency: f=Max frequency*Y2=25.00Hz

y

100%

80%

(

Y2=50%

Y1=20%

AI1,AI2,AI3

X2,Y2)

(X1,Y1)

X2=50%X1=0%

X1=0% , Y1＝20% potentiometer 0V corresponding set value: f=Max frequency*Y1=10.00Hz

10V

100%

x

X2=50%, Y2＝50% potentiometer 5V corresponding set value: f=Max frequency*Y2=25.00Hz

y

(

X2=100%

100%

10V

X2,Y2)

x

100%

Y2=100%

AI1,AI2,AI3

Y1=-100%

0%,Y1＝-100% potentiometer 0V corresponding set frequency:f=Max frequency*Y1=-50.00Hz

X1=

X1=0%

(X1,Y1)

50%

5V

X2=100%,Y2=100%potentiometer 10V correspond set frequency:f=maximum frequency*Y2=50.00Hz

53

Skipping thread of AI1, AI2, AI3 respectively are JP3/JP5, JP6, JP7, seeing the following detailed

specification:

o12 AI1 Input Filter Time 0.00~2.00 s 0.10 Y

o13 AI2 Input Filter Time 0.00~2.00 s 0.10 Y

o14 AI3 Input Filter Time 0.00~2.00 s 0.10 Y

Filter time constant of analog signal input, that is 0.00~2.00s.If time parameter is set too long, the
changement of setting frequency will be stable, but responsing speed will be slow;If time parameter is
set too short, the changement of setting frequency will not be stable, but responsing speed will be quick.

Section V

N reaction 0

Setting frequency 1

Actual frequency 2

Actual current 3

o15

DA1 Output Terminal

o16

DA2 Output Terminal

Output voltage 4

DC bus voltge 5

-

-

-

Y

-

Y

IGBT temperature 6

Output power 7

Output RPM 8

Actual value of torque 9

DA1 Adjustment Of

o17

Lower Limit Output

DA1 Adjustment Of

o18

Upper Limit Of Output

DA2 Adjustment Of

o19

Lower Limit Output

DA2 Adjustment Of

o20

Upper Limit Output

0.0~100.0 % 0.0 Y

0.0~100.0

0.0~100.0

0.0~100.0

% 100.0 Y

% 0.0 Y

% 100.0 Y

Output Content Setting Value Giving Output Singla Range

N Reaction 0

Setting
Frequency

Actual
Frequency

1

2

Actual Current 3

Output Voltage 4

DC Bus Voltage 5

IGBT
Temperature

6

N output

0~Max frequency

0~Max frequency

0~200%, corresponding parameter: S03 percentage

of output curent
0~200%, corresponding parameter: b02、b15 rate

voltage of motor

0~1000VDC, DC voltage

0~100.0℃

54

Section V Parameter Function Table

Section

V

Section V Parameter Function Table

Output Power 7

Output RPM 8

Actual Value Of
Torque

the corresponded
output frequency

0Hz

10.0%

0V/0mA

9

DA1

20.0%

0~200%

0~Max RPM

0~200% torque

DA2

50.0%

100.0%

10V/20mA

Voltage/Current

This parameter is used for setting upper/lower limitation of DA1/DA2 output signal.

Such as:

If DA1 output 1~5V voltage, setting parameter as: o17＝10.0%, o18＝50.0%
If DA2 output 4~20mA current, setting parameter as: o19＝20.0%, o20＝100.0%

DA1, DA2 Skipping thread:

Caution: Every terminal has choice of voltage output and current output, the default setting is voltage
output. When the voltage output is needed, please connect JP1/JP2 and DA1V/DA2V(seeing the panel);
When the current output is needed, please connect JP1/JP2 and DA1C/DA2C.

o21
o22
o23
o24

O1 Output Signal
Option1
O2 Output Signal
Option 2
O3 Output Signal
Option 3
O4 Output Signal
Option 4

N function 0

Fault warning 1

Over current inspection 2

Over load inspection 3

Over voltage inspection 4

Less voltage inspection 5

-

0

Y

-

0

-

-

Y

1

Y

8

Y

Low load inspection 6

Over heat inspection 7

Running state with command 8

Abnormal PID feedback signal 9

Motor state of REW running 10

Arrival of setting the frequency 11

Arrival of Upper frequency 12

Arrival of Lower frequency 13

Arrival of FDT setting
frequency 1

Arrival of FDT setting
frequency 2

14

15

FDT frequency level inspection 16

Arrival of preset counter value 17

Arrival of upper limit counter

Program running one period
completed

18

19

Speed tricking mode inspecition 20

N command running state 21

REV running from inverter
command

22

Deceleration running 23

Section V

Acceleration running 24

Arrival of high pressure 25

Arrival of low pressure 26

Arrival of inverter rate current 27

Arrival of motor rate current 28

Arrival of input frequency
lower limitation

Arrival of current upper
limitation

Arrival of current lower
limitation

29

30

31

Time to reach limit time 1 32

Time to reach limit time 2 33

Setting

Va l ue

0 N Function

Output Content Specification Explaination

Inverter ready to run 34

Setting “0”, N output reaction, but inverter can be controlled
by theoretical terminal.

1 Fault Warning Inverter at fault or after fault with unconfirmed status.

2 Over Current Inspeciton Inverter met fault of over current

3 Over Load Inspeciton Inverter met fault of over load of heat protection

4 Over Voltage Inspeciton Inverter met fault of over voltage

5 Less Voltage Inspeciton Inverter met fault of less voltge

6 Lower Load Inspection Inverter met fault of lower load

7 Over Heat Inspeciton Inverter met fault of over heat.

8 Running State Of Command Inverter is under running state of command

9 Abnormal PID Feedback Signal PID feedback signal is abnormal

10 Motor State Of REW Running Motor is reverse running

11 Arrival Of Setting Frequency Arrive at set frequency

12 Arrival Of Upper Frequency Arrive at upper frequency

13 Arrival of lower frequency Arrive at lower frequency

55

56

Section V Parameter Function Table

Section

V

Section V Parameter Function Table

14 Arrival Of FDT Set Frequency1 Arrive at frequency 1 FDT set

15 Arrival Of FDT Set Frequency2 Arrive at frequency 2 FDT set

Inspection Level Of FDT

16

Frequency

Arrival Of Preset Counting

17

Va l ue

Arrival Of Counting Value

18

Upper Limitation

Program Ruuning One Period

19

Completion

FDT frequency levels to meet the inspection conditions,o29~
o31

Present counting value arrives at preset counting value

Present counting value arrives at upper limitation of counting
value.

Program runs one period to complete.

20 Inspection In Speed Trick Mode Inverter is under speed trick state, the valid time is A11

21 N Command Running State Inverter is under N command running state

22 REW Command Of Inverter Inverter is under reverse running command

23 Deceleration Running Inverter is under deceleration running

24 Acceleration Running Inverter is under acceleration running

25 Arrival Of High Pressure Arrival at hight pressure

26 Arrival Of Low Pressure Arrival at low pressure

27 Arrival Of Inverter Rate Current Arrival at inverter rate current

28 Arrival Of Motor Rate Current Arrival at motor rate current

Arrival Of Input Frequency

29

Lower Limitation

Arrival Of Current Upper

30

Limitation

Arrival Of Current Lower

31

Limitation

Present set frequency is less than frequency lower limitation

Arrive at current of upper limitation

Arrive at current of lower limitation

32 Time to reach limit time 1 Timing action mode refer to o65 configuration

33 Time to reach limit time 2 Timing action mode refer to o66 configuration

34 Inverter ready to run

The end of initialization when the drive power on , running
command is acceptable.

o25 Output Signal Delay 1 0~32.000

o26 Output Signal Delay 2 0~32.000

o27 Output Signal Delay 3 0~32.000

o28 Output Signal Delay 4 0~32.000

s 0 Y

s 0 Y

s 0 Y

s 0 Y

o25~o28 defines o21~o24 output signal reaction delay time, unit is S.
Output signal cut off action without delay.

o29 FDT Set Frequency 1 o30~Max frequecy Hz 0.00 Y

o30 FDT Set Frequency 2 0~o29 Hz 0.00 Y

o31 FDT Inspection Range 0.00~5.00 Hz 0.00 Y

When the choice of output signal(o21~o24)is set as14, inverter output frequency arrives at or
surpass FDT set frequency 1, the corresponding signal output terminal will react; When inverter output
frequency is below of frequency 1 FDT set, the corresponding signal output terminal will not react.

When the output signal options(o21~o24)is set as 15, inverter output frequency reaches or surpass

FDT set frequency 2, the corresponding signal output terminal will react;When inverter output frequency
is below of frequency 3 FDT set, the corresponding signal output terminal will not react.

When the output signal options (o21~o24)is set as16, inverter will firstly inspect FDT set freuqnecy
1, then inverter output frequency arrives at or surpass FDT set frequency 1, the corresponding signal
output terminal will react;After terminal reaction, inverter will inspect FDT set frequency 2, When
inverter output frequency is below of frequency 2 FDT set, the corresponding signal output terminal will
not react.

o31 frequency inspection range

This parameter is used to define inspection range. When the difference of actual frequency and
inspected frequency has surpassed inspection range, terminal will output react.

e.g.: FDT set frequency 1 as 35Hz, FDT set frequency 2 as 30Hz,

Frequency inspection range is 0, the signal output terminal will react as below:

Section V

output frequency

FDT1=35Hz

FDT2=30Hz

time

setting 1 arrived

FDT frequency

Arrival Of Current

o32

Upper Limitation

Arrival Of Current

o33

Lower Limitation

Current Inspection

o34

Range

current percentage

o32=120
o33=20
o34=3

current upper limitation

current lower limitation

FDT frequency

setting 2 arrived

FDT frequency

inspection level

ON means signal will react, OFF means signal will not react

120

20

ON means signal will reac t, OFF means signal will not react

OFF

OFF

OFF

o34 o34 o34 o34

ON OFF ONOFF

OFF ON OFF

When the output signal options (o21~o24)is set as 30, and inverter output current reach or surpass

OFF

ON

ON

ON

OFF

OFF

ON

time

ON

time

ON

time

o33~200% % 120

o34~o32 % 20

0~o33 % 3

time

OFF

o34 o34

time

time

Y

Y

Y

“o32+o34”, the corresponding output signal terminal will react. When the inverter output current is less
than o32-o34, The corresponding output signal terminal will not react.

57

58

Section V Parameter Function Table

Section

V

When the output signal options (o21~o24)is set as 31, and inverter output frequency reach or less
than o33-o34, the corresponding output signal terminal will react;When the inverter output current is
more than o33+o34, The corresponding output signal terminal will not react.

o34 is used to define current inspection range. When the difference of actual current and inspected
current has surpassed inspection range, The output terminal will react.

o35 Terminal Control Mode

Two-wire running
control 1

Two-wire running
control 2

Three-wire running
control 1

bit

Three-wire running
control 2
One-shot operation
control 1

One-shot operation
control 2

0

1

2

3

- 0000 N

4

5

Terminal command

0

1

10 bit

is invalid after power
on running

Terminal command
is valid after power
on running

Setting terminal running mode by this parameter.

1 Bit set terminal running mode:

The polarity of electrical level is o47 default setting polarity. Low electrical level or falling edge
is valid, and the terminal is leakage-souce driving mode.
X can be used to express high or low electrical level, rising or falling edge.

Running Control Mode

Keyboard Running

Control

Prior Running Prior Direction

Edge Trigger Valid Same Same

E-level Trigger Invalid Prior running Prior FWD

0:

Two wire running control 1

FWD/ STOP

REV/ STOP

F05=1 or F05=4 F05=3

FWD REV FWD REV

FWD

REV

COM

Command

lling edge X Low E Level X FWD running

X Falling edge High E-level Low E-level REV running

Rising edge Rising edge High E-level High E-level STOP running

1: Two wire running control

2

Section V Parameter Function Table

RUN/ STOP

FWD/ REV

F05=1 or F05=4 F05=3

FWD REV FWD REV

FWD

REV

COM

Command

Falling edge Falling edge Low e-level Low e-level FWD running

Falling edge Rising edge Low e-level High e-level REV running

Section V

Rising edge X High e-level X STOP running

2: Three wire running control 1

RUN

FWD/REV

STOP

FWD

REV

STOP

COM

F05=1 ;F05=3; F05=4

FWD REV STOP

Command

Falling edge Low e-level Low e-level FWD running

Falling edge High e-level Low e-level REV running

X X High e-level STOP running

3: Three wire running control 2

FWD

REV

STOP

FWD

REV

STOP

COM

F05=1 ;F05=3; F05=4

FWD REV STOP

Command

Falling edge X Low e-level FWD running

X Falling edge Low e-level REV running

X X High e-level STOP running

4: One-shot operation control 1

FWD/ STOP

REV/ STOP

F05=1；F05=4；F05=3

FWD REV

X FWD running

FWD

REV

COM

Command Current state

STOP running

59

60

Section V Parameter Function Table

Section

V

Section V Parameter Function Table

Keep REV running

X

STOP running

STOP running

FWD running

Keep REV running FWD running

X FWD running REV running

Keep

5: One-shot operation control 2

RUN/ STOP

FWD/ REV

FWD

REV

COM

F05=1；F05=4；F05=3

FWD REV

Low e-level FWD running

High e-level

X
X

10 bit: Set the terminal status when power on

0: Terminal run command invalid when Power on.

Terminal run command invalid when power on,. Only run 3S later after power on and set terminals
invalid.

1: Terminal run command valid when Power on.

Terminal status is effective when power on, inverter will run immediately, in some cases such status
will not be allowable.

o36

(DI1) Input Terminal

o37

Function Selection

o38

(DI2) Input Terminal

o39

Function Selection

o40

(DI3 )Input Terminal

o41

Function Selection

o42

(DI4) Input Terminal

o43

Function Selection

o44

(DI5) Input Terminal

o45

Function Selection

o46

(DI6) Input Terminal
Function Selection
(DI7) Input Terminal
Function Selection
(DI8) Input Terminal
Function Selection
(AI1) Input Terminal
Function Selection
(AI2) Input Terminal
Function Selection
(AI3) Input Terminal
Function Selection

STOP running

Command Current state

REV running

STOP running

STOP running

No function

Forward running FWD

Reverse running REV

3-line mode running STOP

Multi-segment command 1

Multi-segment command 2

Multi-segment command 3

Multi-segment command

Multi-segment speed command 1

Multi-segment speed command

Multi-segment speed command 3

Multi-segment digital voltage 1

Multi-segment digital voltage 2

Multi-segment digital voltage 3

The main set mode 1 of set
frequency

The main set mode 2 of set

REV running

STOP running

STOP running

FWD running
REV running

0

4

61

11

-

-

1

-

2

-

-

3

-

-

5

-

-

6

-

7

-

8

9

10

12

13

14

15

frequency

The main set mode 3 of set
frequency
The auxiliary setting mode 1 of
frequency set

The auxiliary setting mode 2 of
frequency set

The auxiliary setting mode 3 of
frequency set

MSS time running 1 20

MSS time running 2 21

0

Y

0

Y

0

Y

0

Y

0

Y

0

Y

0

Y

0

Y

0

Y

0

Y

0

Y

Section V

MSS time running 3 22

Operation control mode shift 1 23

Operation control mode shift 2 24

Operation control mode shift 3 25

Forward torque limit shift 1 26

Forward torque limit shift 2 27

Forward torque limit shift 3 28

Reverse torque limit shift 1 29

Reverse torque limit shift 2 30

Reverse torque limit shift 3 31

Torque speed shift

fault reset command

FWD JOG command

REV JOG command

JOG order (as F35setting )

Acceleration and deceleration
prohibition command

Motor 1、2 shift

Free stop

Up command

Down command

Automation program running
fuction cancel

Automation program running
stop

Program running start mode

Program running stop mode

Pulse counter clearance

Pulse counter input

Counter loading

62

16

17

18

19

32

33

34

35

36

37

38

39

40

41

42

43

44

45

46

47

48

Section V Parameter Function Table

Section

V

Section V Parameter Function Table

Setting

Va l ue

0

1

2

3

4

5

6

7

8

9

Upper counter loading 49

External default signal input
(level)

1pump soft-start 51

1 pump stop 52

2pump soft-start 53

2 pump stop 54

3pump soft-start 55

3 pump stop 56

4pump soft-start 57

4 pump stop 58

handrotate command 59

Timing Water Supply change
to zero

Extruder acceleration and
deceleration direction

Extruder acceleration and
deceleration allowable

Limit time 1 input

Limit time 2 input

Program switching to the next
segment

UP/DN adjusted value reset

Keyboard potentiometer set
value reset

External default signal input
(edge)

Output Detail Specification Explaination

No- function

Forward command FWD

Reverse command REV

Three line running STOP

Multi-speed command 1

Multi-speed command 2

Multi-speed command 3

Multi-speed command 4

multi-acceleration command 1

multi-acceleration command 2

N- function

Forward command FWD, Can be set to edge triggered or

level-triggered

Reverse command REV, Can be set to edge triggered or

level-triggered

o35 setting 3 line running, STOP function

Synthes is of16 multi-speed settings.See H parameter Group

Synthes is of 8 acceleration settings.See H parameter Group

63

10

multi-acceleration command 3

11

50

Section V

60

61

62

63

64

65

66

67

68

multi-segment digital voltage 1

12

multi-segment digital voltage 2

13

multi-segment digital voltage 3

The main set mode 1 of set

14

frequency

The main set mode 2 of set

15

frequency

The main set mode 3 of set

16

frequency
The auxiliary setting mode 1

17

of frequency set

The auxiliary setting mode 2

18

of frequency set

The auxiliary setting mode 3

19

of frequency set

20 MSS timing running 1

21 MSS timing running 2

22 MSS timing running 3

23 Operation control mode shift 1

24 Operation control mode shift 2

25 Operation control mode shift 3

26 Forward torque limit shift 1

27 Forward torque limit shift 2

28 Forward torque limit shift 3

29 Reverse torque limit shift 1

30 Reverse torque limit shift 2

31 Reverse torque limit shift 3

32 Torque speed shift

33

Fault reset command

34

FWD JOG command

35

REV JOG command

36

JOG command(as F35 setting)

Acceleration and deceleration

37

forbid commandr

38

Motor 1、2 shift

1

Synthes is of8digital voltage settings.See H parameter Group

Synthesized frequency given to the way the main switch. See

F parameter group

Synthesized frequency secondary to the way a given switch.

See F parameter set

Synthes is of segment8 run time setting. See H parameter set.

Synthes is of operation mode switching. Read F05 parameter

Synthes is of reverse torque limit switch.See C parameter set

C15 Group

Synthes is of reverse torque limit switch.See C parameter set

C16 Group

Vector control mode, speed control mode and torque control

mode switching.

Disconnected status: Speed Control

Closed Status: torque control

Detail C parameter set C18

Edge-triggered, the fault occurred on the current failure to

confirm or not confirm

JOG forward running command

JOG reverse running command

JOGrunning command,direction,set a direction in accordance

with F35.

To maintain the current state to prohibit the acceleration and

deceleration movements.
Motor 1、2 change

Invalid status : Motor 1

64

Section V Parameter Function Table

Section

V

Section V Parameter Function Table

39

Free stop

40

Up command

41

Down command

Auto-run feature programs

42

canceled

Automatic procedures to

43

suspend operation

44 program running start mode

45 program running stop mode

46

pulse count clearance

47

pulse count input

48 before count loading

49 upper count loading

External default signal input

50

(level)

51 1 pump soft-start

52 1 pump stop

53 2 pump soft-start

54 2 pump stop

55 3pump soft-start

56 3 pump stop

57 4 pump start

58 4 pump stop

59 Hand change order

the period of time water

60

supply change to zero

Extruder acceleration and

61

deceleration direction

Extruder acceleration and

62

deceleration allowable

Limit time 1 input

63

Valid status : Motor 2

Free stop:After free stop, no start command,after 1s, allows

running again

Up order

Down order

, detail A38~A42

, detail A38~A42

Cancle program running function

program running pause

program running start mode

program running stop mode

Edge-triggered,frequency inverter pulse countero53Clearance

Edge-triggered, set the pulse counter input terminal

Edge-triggered, pulse-load preset counter o53counts to o54

Edge-triggered pulse counter counts o5 maximum load o53

External default signal input(level)，level trigger , the

system will alarm E_Set after valid

Electric leverl spring, control 1 pump soft-start or stop.

soft-start control must use 2 terminal control, stop priority.

Need to set E01 load model 9, E12 1pump is soft-start

control pump.

Electric leverl spring, control 2 pump soft-start or stop.

soft-start control must use 2 terminal control,stop priority.

Need to set E01 load model 9, E12 2pump is soft-start

control pump.

Electric leverl spring, control 3 pump soft-start or stop.

soft-start control must use 2 terminal control, stop priority.

Need to set E01 load model 9 , E12 3pump is soft-start

control pump.

Electric leverl spring, control 4 pump soft-start or stop.

Soft-start control must use two terminal control, stop has

the priority.

Need setting E01 load style 9, E12 4 pump is soft - start

control pump.

electric level spring, automation multi-pump constant water

changed

electric level spring the period of time water supply change to
zero

DIx input terminal function selection, read o36- 046

DIx input terminal function selection, read o36-046.

DIx input timeing - limit time 1, refer to o65, o67.

Limit time 2 input

64

Program switching to the

65

next segment

UP/DN adjusted value reset

66

Keyboard potentiometer set

67

value reset

External default signal input

68

o47

command is valid or not when power on.

Section V

(edge)

Polarity of input and
output terminals

This parameter used to select every IO terminal is valid in which polarity and terminal running

14 13 0123456789101112

15

2222222222222222

15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0

O4
O3
O2
O1

leave unused

AI3
AI2

DIx input timeing - limit time 2, refer to o66, o68

Program running controlled, single trigger switch to the next

segment

A40 UP/DN adjusted value reset, level trigger.

A47keyboard potentiometer setting value reset level trigger.

External default signal input, edge trigger (falling edge),the

system will alarm E-Set after valid

0000~F7FF - 0000 Y

DI1
DI2
DI3
DI4
DI5
DI6
DI7
DI8AI1

0~10 bit Input Terminal Polarity 12~15 bit Output Terminal Polarity

Low level valid(closed)

0

1

Input Terminal Teponse

o48

Time 0

Input Terminal Reponse

o49

Time 1

o48,o49define

Input Terminal Reponse

o50

Time Selection

o48, o49 define

Falling edge valid, rising edge invalid

High level valid(disconnected)

Rising edge valid, falling edge invalid

Input terminal reponse time

Input terminal reponse time

0.001~30.000 s 0.005 Y

0.001~30.000 s 0.005 Y

,through o50select the reponse time according theterminal.

0~07FF - 0 Y

, through o50 select the reponse time according

0 Lo w level valid(closed)

1 High level valid(cut off)

theterminal.

The delay time of the input terminal is valid to the close and cut off action!
Set the parameter choose

Input terminal reponse time according every terminal.

Setting 0~10 the polarity of input terminal

0 o48 input terminal reponse time 0

1 o49 input terminal reponse time 1

65

66

Section

V

Section V Parameter Function Table

7654

222

10

98

8910

3210

22222222
01234567

DI1
DI2
DI3
DI4
DI5
DI6
DI7

DI8
AI1
AI2
AI3

1 bit

Circle counter
operating

Single cycle counter
running

0

1

Arrive at upper

0

1

10 bit

counter value and
reload

Arrive at upper
counter value and
clear savings

o51

Counter Collocation

100 bit

Power on to reload 0

power on to clear
savings

power on to keep
previous count status

- 0 Y

1

2

Count period 0

1000 bit

Output signal valid
time 20ms

Output signal valid
time 100ms

Output signal valid
time 500ms

1

2

3

1 bit: Control count mode

0: Circulate count, Arrive at upper counter value, ouput the arrival pulse(output terminal setting)
1: single circulate count, after arrive at upper counter value, output the arrival pulse, stop running.

10 bit : Operating after circulate mode reach upper limit count

0: Reload
1: Clear up

100 bit: Define the status of the counter after power on

0: Reload after power on
1: Clear up after power on

2: Keep the status of the previous count
1000 bit: Define o21~o24 is set to reach the preset count or counts to reach the maximum output signal
delay time

0: Count period, when reach this digital, keep this status valid, direct the change of the count.

1: the valid time of the output signal10ms, when reach this count, fixed keep the output status valid

10ms.

2: the valid time of the output signal 100ms, when reach this count, fixed keep the output status

valid 100ms.

3: the valid time of the output signal 500ms, when reach this count, fixed keep the output status

67

Section V Parameter Function Table

valid 500ms.

Maximum Pulse Input

o52

Frequency

0.1~50.0 kHz 20.0 Y

This parameter define the most pulse input frequency of analog setting frequency .
Input high signal frequency, only through multi-function input terminal Di8 as the pulse input

terminal.

input pulse setting frequency according the the most input upper limit.
input pulse setting frequency, most input pulse frequency o52according the most output frequency

F12.

Pulse input frequency f_pulse corresponding setting frequency f_set formula:f_set＝f_pulse/o52*F12.
Pulse input analog setting, input most pulse frequency o52 according 100.0%.
Pulse input frequency f_pulse corresponding analog p_set formula: p_set＝f_pulse/o52*100.0%.

o53

Current Counter Status

Section V

o54

Preset Counter Setting

Upper Limit Counter

o55

Setting

1

DiX counting

o21

o22

0

0~9999 - 0 Y

0~ o55 - 0

o54~9999 - 9999

2345634 5 63

o54

T

the thousand of O51 set t

o54

T

o55

T

o55

T

Y

Y

When the pulse signal of the input terminal satisfy with the preset condition, Yi terminal output the

corresponding indication.
1 、Selection of Input terminal DiX（X=1~8）

Input terminal is set to “pulse count input ”, and set o54、o55.
Input terminal is set to “pulse counter clear”, after terminal works, counter is cleared.
Input terminal is set to “upload of pulse count value”, after terminal works, counter uploads preset

count value.

Input terminal is set to“upload of upper count value”,after terminal works,counter uploads the upper

count value.
2 、Selection of Output Terminal o21~o24

o21set the arrival of preset count, the effective time of output signal after reaching up count value is

set by o51.

o22 set the arrival of up count value, the effective time of output signal after arriving at the upper

count value is set by o51.

Frequency range of counting pulse signal: 0~100Hz.

Virtual Terminal

o56

Effective Selection

This parameter is used to select a terminal whether each virtual terminal functionality is valid.

O4
O3
O2
O1

leave unused

AI3
AI2

14 13 0123456789101112

15

2222222222222222

15 14 13 12 11 10 9 876

0000~F7FF - 0000 Y

54

3210

DI1
DI2
DI3
DI4
DI5

DI6
DI7
DI8AI1

68

Section V Parameter Function Table

Section

V

Section V Parameter Function Table

Setting 0~10

0

o57

DI1~4 T erm ina l S tat us

o58

DI5~8 Termin al St at us

o59

AI1~3 Terminal Status

o60 O1~4

Make the actual terminal can only be effective check terminal state.
Make the

o61

PL1 Pulse Output

o62

PL2 Pulse Output

o63 SPA pulse output ratio 1~1000 - 1 Y

o64 SPB pulse output ratio 1~1000 - 1 Y

1

Terminal Status

terminal can only be effective through register check terminal state.

Virtual

Virtual terminal valid choose

Actual input terminal valid

Virtual input terminal valid

0000~1111 - - Y

0000~1111 - - Y

000~111 - - Y

0000~1111 - - Y

No action 0

Set frequency 1

Actual frequency 2

Actual current 3

Output voltage 4

DC bus voltage 5

IGBT temperature 6

Output power 7

Output rpm 8

Actual torque 9

-

0

-

0

SPA, SPB provide two isolated pulse output signal can be analogical multiple analog output
signals.

SPA, SPB provide high speed pulse output function. Set by o61~o64 and set functions
valid when inverter power on again.

SPA corresponding output signal 1, this function selected, o21 DO1 output action is invalid.

SPB corresponding output signal 2, this function selected, o22 DO2 output action is invalid.

Pulse output ratio = 1, output signal range 0 ~ 50hz.

Maximum pulse output frequency 50 Khz, minimum frequency 1hz.

for example

SPA pulse output options = 2 Actual frequenciy ;

SPA pulse output options = 10

The actual output pulse frequency = actual frequency / maximum frequency * 50hzx10.

SPA pulse output options =3 Actual current

SPB pulse output ratio=20

The actual output pulse frequency = actual current percentage 200*50hz*20

Output Set Value Output Signal Range Definition

No action 0

Set frequency 1

No output

0~Max frequency

Actual
frequency

Actual current 3

Output voltage 4

Bus voltage 5

IGBT
temperature

Output power 7

Output torque 8

Actual torque
value

Section V

Limit time 1

o65

configuration

Y
Y

o66

Limit time 2

configuration

1 Bit: Timing mode

0 Boot time , timing of runnig and breaking

1 Running timing，only timing of running
10 Bit：Reserved
100 Bit：Reserved
1000 Bit：Reserved

o67 Limit Time 1 0.0~3200.0 s 2.0 Y

o68 Limit Time 2 0.0~3200.0 s 2.0 Y

Set timeing of limit time 1 , Time limit 2

2

0~Max frequency

0~200%, corresponding paramerter: S03 output current percentage

0~200%, correlation parameter: b02、b15 motor rated voltage

0~1000V DC voltage

6

0~100.0℃

0~200%

0~Max torque

9

0~200% torque

Boot time

1 Bit

Running timing

10Bit Reserved

100Bit Reserved

1000Bit Reserved

0

1

-

-

-

- - 0000

0000Y Y

Actual limit time on the basis of the set time multiplied by a run time multiple, such time

multiple set by the ten bit of F49, refer to F49 instructions.

5-6. Multi-speed PLC Group:H00-H55(0x0300-0x0337)

Factory

Code Description / LCD Setting Range Unit

1 bit

10 bit

Program running
function cancel

Program running
function

Direction decided by
H40~H46

Direction decised by
Terminal and
keyboard

Deceleration and
acceleration time
decised by H26~H39

0

1

0

1

0

- 0000

H00 Multi-speed Collocation

100 bit

Setting

Change

Limited

Y

69

70

Section V Parameter Function Table

Section

V

g

Section V Parameter Function Table

Time of acceleration
and deceleration

1

isdecided by terminal

1000 bit

Running time
decised by H18~H25

Running time
decised by terminal

0

1

1 bit: Program running functions intelligent

To use the program to run PLC functionality requires setting the bit to 1.
Multi-segment speed run only need to set the corresponding multi-stage o36 ~ o46-speed switching
can be used without the need to set this parameter.
0: Program running functions cancel
1: Program running function intelligent

10 bit: Define program runs or direction settings of multi-segment speed running

0: the direction decided by the H40 ~ H46
1: The directiondecided by the keyboard or terminal

100

bit:Define program runs or acceleration and deceleration time settings of multi-segment speed runnin

0: deceleration time decided by the H26 ~ H39
1: The acceleration and deceleration time determined by terminal

1000 bit: Set running time of defined program running

0: running-time decided by the H18 ~ H25
1: Running time decided by terminal

H01

Program Running
Configuration

1 bit

10 bit

100 bit

1000 bit

sequence control

terminal control

Program running
start segment
Program running end
segment

Output signal valid
time 8ms

Output signal valid
time 20ms

Output signal valid
time 100ms

Output signal valid
time 500ms

0

1

0~15

0~15

- 0710

0

1

2

3

1 bit: program run control mode。

0: sequential control
Run automatically according to the start segment,end segment and program running time of program
running.
You can use o36 ~ o46 switchover next function , switchover to the next program running .
1: Terminal control
Use multi segment control terminal o36 ~ o46 multi segment instruction 1, 2, 3, 4, Control program
segment, running time arrives,Running based on the 0 paragraph speed. After Multi - Stage speed
control terminal switchover, reevaluate running time
Do not use of multi - stage speed control terminal o 36 ~ o46 multi - speed instruction, You can use
o36 ~ o46 switchover next function. The terminal control for single trigger, triggered once, program
running to next paragraph, running time recalculated.Running time of arrival, Running based on the
0 paragraph speed.

10 bit: defining the start running of the Program
100 bit: Defines the end of the program period
1000 bit: Define effective time of the program output signal

single-cycle

Continuous Cycle 1

1 bit

One-cycle command
running

The zero speed
running when pause

10 bit

Fixed-speed running
when the suspension

H02 Program Running Mode

Section V

100 bit

Stop with the
parameters set when
stop

Stop with the settings
of start up

0

2

0

1

-

0

0000

Y

1

Running at the speed

0

1

1000 bit

when start up
segment

Running at the speed
before the machine
stopped

1 bit: Running cycle

0:

single cycle

1：continuous cycle
2: Single cycle, running according to H01 speed of the end,stop after accepted the stopped orders.
The program runs three styles as following:
Eg1:The program

Y

output

frequency

60Hz
50Hz
40Hz

30Hz

20Hz

10Hz

10Hz

0

is run single - cycle modes

3X

2X

1X

4X

T3

T1

T2

T4

5X

6X

7X

T7

T6

T5

time

Eg2:program run Continuous cycle modes

putput

frequency

60Hz
50Hz
40Hz

30Hz

20Hz

10Hz

0

10Hz

program
running
STOP

5X

6X

3X

2X

1X

7X

1X

4X

5X

6X

3X

2X

7X

2X

1X

4X

time

Eg3:Program is running in single cycle, According to Paragraph seventh of Speed mode

71

72

Section V Parameter Function Table

Section

V

Section V Parameter Function Table

output

frequency

60Hz
50Hz
40Hz

30Hz

20Hz
10Hz

10Hz

program
running

STOP

2X

1X

0

5X

6X

3X

4X

7X

time

10 bit: Running condition when pause

0: speed run when pause
1: fixed Segment Speed operation when pause

100 bit: Running Segment when stop

0: Set stopping according to the parameters of stop segment.
1: Set down to the initial segment

1000 bit: start Running Segment

0: Set down to the speed running

1: Running at the speed before the machine stopped.
100 bit=0 Set stopping according to the parameters of stop segment
1000 bit=0 running at Start Segment

output
frequency

F51=00

RUN

STOP

T1

3X

2X

1X

X

T2

at1'

dt3'

Eg:100 bit==0 Set stopping according to the parameters of stop segment
1000 bit==1 Running at the speed before the machine stopped.

output
frequency

F51=01

RUN

STOP

3X

2X

1X

X+Y=T3

X

T2T1

at3'

dt3'

Eg:100 bit=1 Set down to the initial segment
1000 bit=1 Running at the speed before the machine stopped.

output
frequency

F51=10,11

RUN

STOP

T1

3X

2X

1X

X

T2

at1'

dt1'

Note ：at1＇：at the time of segment 1 acceleration time ；dt1＇：at the time of segment 1 deceleration
time ；at3＇at the time of segment 3 acceleration time；dt3＇：at the time of segment 3 deceleration time

3X

2X

1X

T1

T2

time

5X

4X

3X

Y

T4

time

3X

2X

1X

T1

T2

time

1 Segment Speed

H03

Setting 1X

2 Segment Speed

H04

Setting 2X

3 Segment Speed

H05

Setting 3X

4 Segment Speed

H06

Setting 4X

5 Segment Speed

H07

Setting 5X

6 Segment Speed

H08

Section V

H09

H10

H11

H12

H13

H14

H15

H16

H17

Setting 6X

7 Segment Speed
Setting 7X

8 Segment Speed
Setting 8X

9 Segment Speed
Setting 9X

10 Segment Speed
Setting 10X

11 Segment Speed
Setting 11X

12 Segment Speed
Setting 12X

13 Segment Speed
Setting 13X

14 Segment Speed
Setting 14X

15 Segment Speed
Setting 15X

Lower frequency ~ upper frequency Hz

Lower frequency ~ upper frequency Hz

Lower frequency ~ upper frequency Hz

Lower frequency ~ upper frequency Hz

Lower frequency ~ upper frequency Hz

Lower frequency ~ upper frequency Hz

Lower frequency ~ upper frequency Hz

Lower frequency ~ upper frequency Hz

Lower frequency ~ upper frequency Hz

Lower frequency ~ upper frequency Hz

Lower frequency ~ upper frequency Hz

Lower frequency ~ upper frequency Hz

Lower frequency ~ upper frequency Hz

Lower frequency ~ upper frequency Hz

Lower frequency ~ upper frequency Hz

3.00 Y

6.00 Y

9.00 Y

12.00 Y

15.00 Y

18.00 Y

21.00 Y

24.00 Y

27.00 Y

30.00 Y

33.00 Y

36.00 Y

39.00 Y

42.00 Y

45.00 Y

Set the frequency of program running and the running frequency of 7-segment speed respectively.
short-circuit the multi-terminal command 1, 2, 3, 4 with COM combinatorially to realized the 16-segment
speed/acceleration speed.

0Xspeed is the regular running mode,setting source can be adjusted by F02,F03and other parameters,
running time is controlled by the H18.

Terminal multi-segment speed is defined as follows(shorted with COM it is ON, disconnected then it
is OFF):

Speed

Ter mi na l

0X 1X 2X 3X 4X 5X 6X 7X

Multiterminal-speed Command 1 OFF ON OFF ON OFF ON OFF ON

Multiterminal-speed Command 2 OFF OFF ON ON OFF OFF ON ON

Multiterminal-speed Command 3 OFF OFF OFF OFF ON ON ON ON

Multiterminal-speed Command 4 OFF OFF OFF OFF OFF OFF OFF OFF

Speed

Ter mi na l

8X 9X 10X 11X 12X 13X 14X 15X

Multiterminal-speed Command 1 OFF ON OFF ON OFF ON OFF ON

Multiterminal-speed Command 2 OFF OFF ON ON OFF OFF ON ON

73

74

Section V Parameter Function Table

Section

V

Section V Parameter Function Table

Multiterminal-speed Command 3 OFF OFF OFF OFF ON ON ON ON

Multiterminal-speed Command 4 ON ON ON ON ON ON ON ON

Acceleration and deceleration time and the direction of running

0X-7X 8X-15X

0 0X -7X Direction controlled by parameter

0X -7X Direction controlled by keyboard

1

and terminal

0X -7Xdeceleration and accelertation time

0

controlled by parameter

0X -7X deceleration and accelertation time

1

controlled by terminal

0X -7Xrunning time controlled by

0

paremeter

1 0X -7Xrunning time controlled by terminal

0 Segment Running
Time T0

1 Segment Running
Time T1

2 Segment Running
Time T2

3 Segment Running
Time T3

4 Segment Running
Time T4

5 Segment Running
Time T5

6 Segment Running
Time T6

7 Segment Running
Time T7

0.0~3200.0 s 2.0 Y

0.0~3200.0 s 2.0 Y

0.0~3200.0 s 2.0

0.0~3200.0 s 2.0

0.0~3200.0 s 2.0

0.0~3200.0 s 2.0

0.0~3200.0 s 2.0

0.0~3200.0 s 2.0

8X-15X Direction controlled

by keyboard and terminal

8X-15Xdeceleration and

accelertation time controlled

by keyboard and terminal

8X-15Xrunning time controlled

by terminal

1000 bit

H18

H19

H20

H21

H22

H23

H24

H25

H00

10 bit

H00

100 bit

H00

Actual running time equals to the set multi-segment running time multiples a time which is times of

speed running time, and such actual running time decided by the tens digit of H40~H46. Please refer to

H40~H46.

1 Segment

H26

Acceleration Time at1

1 Segment

H27

Deceleration Time dt1

2 Segment

H28

Acceleration Time at2

2 Segment

H29

Deceleration Time dt2

3 Segment

H30

Acceleration Time at3

3 Segment

H31

Deceleration Time dt3

0.0~3200.0 s 10.0

0.0~3200.0 s 10.0

0.0~3200.0 s 10.0

0.0~3200.0 s 10.0

0.0~3200.0 s 10.0

0.0~3200.0 s 10.0

75

4 Segment

H32

Acceleration Time at4

4 Segment

H33

Deceleration Time dt4

5 Segment

H34

Acceleration Time at5

5 Segment

H35

Deceleration Time dt5

6 Segment

H36

Acceleration Time at6

6 Segment

H37

Section V

Deceleration Time dt6

7 Segment

H38

Acceleration Time at7

7 Segment

H39

Deceleration Time dt7

0.0~3200.0 s 10.0

0.0~3200.0 s 10.0

0.0~3200.0 s 10.0

0.0~3200.0 s 10.0

0.0~3200.0 s 10.0

0.0~3200.0 s 10.0

0.0~3200.0 s 10.0

0.0~3200.0 s 10.0

Y

Y

Y

Y

Y

Y

Y

Y

Set the Acc/Dec time of 7 steps respectively. They determine the time needed to reach the speed,
respectively depending on the acceleration time for acceleration or on the deceleration time for
deceleration, but the time is not the actual time needed. Actual acc/dec time equals to the set acc/dec
time multiples a time multiple which is decided by the hundreds and thousands digit of H40~H46.
Please refer to H40~H46.

Definite acceleration and deceleration time for multi-step speed:

Y

Y

Y

Y

Y

Y

output

frequency

1X

at1

at2

Definition of multi-step speed acceleration/deceleration time

2X

3X

T2T1

T3

dt3dt2

time

Remark: at1: 1 segment acceleration time;at2: 2 segment acceleration time;dt2: 2 segment deceleration

time;dt3: 3 segment deceleration time.

H40

1 Segment Speed

H41

Configuration Word

H42

Y

Y

Y

2 Segment Speed

H43

Configuration Word

H44

3 Segment Speed

H45

Configuration Word

H46

4 Segment Speed
Configuration Word
5 Segment Speed

Y

Configuration Word
6 Segment Speed

Y

Y

Configuration Word
7 Segment Speed
Configuration Word

100 bit

Running direction:
forward

1 bit

Running direction:
reverse

Running time:
*seconds

Running time:
*munites

10 bit

Running time:
*hours

Running time: *days 3

Acceleration time:
*seconds

Acceleration time:
*munites

76

-

0

1

0

1

0000

-

0000

-

0000

-

0000

-

0000

-

0000

-

0000

Y
Y
Y
Y
Y
Y
Y

2

0

1

Section V Parameter Function Table

Section

V

Section V Parameter Function Table

1000 bit

Acceleration time:
*hours

Acceleration time:
*days

Deceleration time:
*seconds

Deceleration time:
*munites

Deceleration time:
*hours

Deceleration time:
*days

2

3

0

1

2

3

1 bit: Under multi-segment program running, the“1 bit”parameter decides the direction of each segment

speed.

Running Direction Setting Value

forward 0

reverse 1

When running control modeF05＝0/1/2,these parameters decide the direction of each segment

speed.

When running control mode F05＝3, the setting value and terminal FWD/REV decide the direction

of each segment speed together. FWD is prior.

FWD=1

Running direction

forward

reverse

10 bit: Unit of multi-segment speed program running time.

Running Time 10 bit Range(e.g.H18~H25=3200.0)

*seconds

*minutes

*hours

*days

100 bit, 1000 bit : Unit of acc/deceleration time of multi-segment speed program running

Acceleration

/ Deceleration time

*seconds

*minutes

*hours

H47

H48

H49

*days

0 Segment Digital

Voltage Giving

1 Segment Digital

Voltage Giving

2 Segment Digital

Voltage Giving

REW =1

Running direction

reverse

forward

Setting Value

0

1

0 3200.0 seconds

1 3200.0 minutes

2 3200.0 hours

3 3200.0 days

1000 bit, 100bit

Range(e.g.H26~H39=3200.0)

0 3200.0 seconds

1 3200.0 minutes

2 3200.0 hours

3 3200.0 days

-100.0~100.0 %

-100.0~100.0 %

-100.0~100.0 %

0.0 Y

10.0 Y

20.0 Y

77

3 Segment Digital

H50

Voltage Giving

4 Segment Digital

H51

Voltage Giving

5 Segment Digital

H52

Voltage Giving

6 Segment Digital

H53

Voltage Giving

7 Segment Digital

H54

Voltage Giving

Digital voltage set function can analogy give
or feedback, select by P02, P03;it

Section V

H55

Multi-speed Status

-100.0~100.0 %

-100.0~100.0 %

-100.0~100.0 %

-100.0~100.0 %

-100.0~100.0 %

frequency

can

be shifted by the input terminal o36~o46.

, select by F02, F03;analogy give PID set

1 bit Current speed step 0~0xF

Current acceleration

10 bit

100 bit

1000 bit

segment

Current running time
segment

Current digit voltage
segment

0~0x7

0~0x7

0~0x7

30.0 Y

40.0 Y

50.0 Y

60.0 Y

70.0 Y

- - N

1 bit: Current speed segment

0~16 segment, In hex, can be shifted t by

o36~o46

10 bit: Current acceleration segment

0~7 segment, in hex, can be shifted by

o36~o46

100 bit: Current running time segment

0~7 segment, in hex, can be shifted by

o36~o46, valid when program running

1000 bit: Current digital voltage segment

0~7 segment, in hex, can by shifted by terminal

o36~o46

5-7. V/Fcurve Group:U00-U15(0x0400-0x040F)

Factory

Code Description / LCD Setting Range Unit

Setting

Change

Limited

U00 V/ Setting Frequency1 0.00~U02 Hz 5.00 N

User-defined the first frequency value of V / F curve, corresponding to V1

output voltage

max
output

V8

V7

V6
V5
V4

V3

V2
V1

(0,0)

F1

F2 F3 F4 F5 F6 F7 F8

max
frequency

output frequency

U01 V/F Setting Voltage 1 0~U03 % 10 N

User-defined the first voltage percentage of V / F curve, on the base of rated output voltage 100%
of frequency inverter, corresponding to F1.

78

Section V Parameter Function Table

Section

V

Section V Parameter Function Table

U02 V/F Setting Frequency 2 U00~U04 Hz 10.00 N

User-defined the second frequency value of V / F curve, corresponding to V2.

U03 V/F Setting Voltage 2 U01~U05 % 20 N

User-defined the second voltage percentage of V / F curve, on the base of rated output voltage

100% of frequency converter, corresponding to F2.

U04 V/F Setting Frequency 3 U02~U06 Hz 15.00 N

User-defined the third frequency value of V / F curve, corresponding to V3.

U05 V/F Setting Voltage 3 U03~U07 % 30 N

User-defined the third voltage percentage of V / F curve, on the base of rated output voltage 100%

of frequency converter, corresponding to F3.

U06 V/F Setting Frequency 4 U04~U08 Hz 20.00 N

User-defined the fourth frequency value of V / F curve, corresponding to V4.

U07 V/F Setting Voltage 4 U05~U09 % 40 N

User-defined the fourth voltage percentage of V / F curve, on the base of rated output voltage 100%

of frequency converter, corresponding to F4.

U08 V/F Setting Frequency 5 U06~U10 Hz 25.00 N

User-defined the fifth frequency value of V / F curve, corresponding to V5.

U09 V/F Setting Voltage 5 U07~U11 % 50 N

User-defined the fifth voltage percentage of V / F curve, on the base of rated output voltage 100%

of frequency converter, corresponding to F5.

U10 V/F Setting Frequency 6 U08~U12 Hz 30.00 N

User-defined the sixth frequency value of V / F curve, corresponding to V6.

U11 V/F Setting Voltage 6 U09~U13 % 60 N

User-defined the sixth voltage percentage of V / F curve, on the base of rated output voltage 100%

of frequency converter, corresponding to F6.

U12 V/F Setting Frequency 7 U10~U14 Hz 35.00 N

User-defined the seventh frequency value of V / F curve, corresponding to V7.

U13 V/F Setting Voltage 7 U11~U15 % 70 N

User-defined the seventh voltage percentage of V / F curve, on the base of rated output voltage

100% of frequency converter, corresponding to F7.

U14 V/F Setting Frequency 8 U12~most frequency Hz 40.00 N

User-defined the eighth frequency value of V / F curve, corresponding to V8.

U15 V/F Setting Voltage 8 U13~100 % 80 N

User-defined the eighth voltage percentage of V / F curve, on the base of rated output voltage 100%

of frequency converter, corresponding to F8.

5-8. PID parameter:P00-P12(0x0500-0x050C)

Code Description / LCD Setting Range Unit

1 bit

Unidirectional

regulation

Bidirectional

regulation

79

0

1

P00 PID Configuration

Factory

Setting

- 0000 N

Change

Limited

Negative effect 0

10 bit

Positive effect 1

PID fault, N action 0

100 bit

War n ing &
Continuous running

War n ing &
Decelerating stop

1

2

Warning & Free stop 3

-

-

M

PID

-

-

inverter

feedback signal

f

1000 bit

Section V

When the inverter receives running command, it can control output frequency automatically in the
PID regulation mode after comparing the setting signal and feedback signal from terminal. The process
is explained as following:

setting signal

+

-

( = setting signal - feedback signal)

PI8000/PI8100 PID regulation

0: negative action, when ＞0 is positive, frequency rises and when ＜0 is negative, frequency
falls.

1: positive action, when ＞0 is positive, frequency falls and when ＜0 is negative, frequency
rises.
PID abnormity treatment:

1: Warning & Continuous running: continue running g after abnormity feedback signal.

2: Warning & Decelerating stop: decelerate and stop after abnormity feedback signal.

3: Warning & Free stop: free stop after abnormity feedback signal .

P01 PID Output Limit 0~100 % 100 Y

The parameter defines the limited range of the output when using PID control.

Set frequency by keyboard or
RS485

0

AI1 external analogy giving 1

P02

Feedback Signal
Selection

AI2 external analogy giving 2

AI3 external analogy giving 3

Keyboard potentiometer giving

- 1 Y

4

muti-step digital voltage giving 5

Digital pulse set 6

PID feedback signal selection, can select keyboard/Rs485, potentiometer, digital voltage, digital
pulse for feedback signal.

P03 Setting Signal Selection

Set frequency by keyboard or
RS485

- 2 Y

0

AI1 external analogy giving 1

AI2 external analogy giving 2

AI3 external analogy giving 3

Keyboard potentiometer giving 4

80

Section V Parameter Function Table

Section

V

Section V Parameter Function Table

Multi-step digital voltage giving 5

Digital pulse set 6

PID giving signal selection, can select keyboard/Rs485, potentiometer, digital voltage, digital pulse

for giving signal.

P04 Keyboard Set Signal 0.0~100.0 % 50.0 Y

When P03 is 0, the setting pressure set by the keyboard. 0.0~100.0% is 0 to the maximum pressure

respectively.

P05 PID integral time 0.002~10.000 s 0.250 Y

0.002~10.000s

The PID integral time determines the integral regulation speed,the regulation acts on the difference

between PID feedback and setting value by PID regulator.

When the difference between PID feedback and setting value is 100% , integral regulator PID

regulator ouput=(P01*F12*12.5%)Hz.(single direction PIDregulation,ignores proportion and differential

effect).

If the value is great,the control is stable but response is slow;if the value is little,the system response

is rapid but perhaps surge occurs.

difference

time

operation value

time

P06 PID Differencial Time 0.000~10.000 s 0.000 Y

0.000~1.000s
The parameter determines the regulation intensity, the regulation acts on the change ratio of the

difference between PID feedback and setting value by PID regulator.

When the change ratio of the difference between PID feedback and setting value is 100% in the

differential time, PID regulator regulates output to(P01*F12*12.5%)Hz (single direction PID regulation,
ignores proportion and integral effect).

If the value is great, the greater the intensity is, the system surge is to occur more easily

P07 PID Proportion Gain 0~1000.0 % 100.0 Y

0~100.0%
The PID Proportion Gain defines regulation intensity of PID regulator, the larger the P is, the more

the intensity is.

When proportion gain is 100%,and the difference between PID feedback and getting value is 100%,

PID regulator’s output is(P01*F12*12.5%)Hz(single direction PID regulation,ignores differential and
integral effect).

Proportion gain is the parameter decides PID regulator’s response extent.

If the gain is great, the response is rapid, but if too great, the surge will occur; the gain is little, the
response will lag.

difference

time

operation value

time

P08 PID Sampling Period 0.002~10.000 s 0.010 Y

Set Sampling period of feedback signal.

When set this parameter small, the system response speed to the giving and feedback deviation is

slow, but control is stable.

Section V

When set this parameter low,the system response speed to the giving and feedback deviation is slow,

but easy to cause vibration

P09 Deviation Limit 0.0~20.0 % 5.0 Y

Deviation limit effects system control accuracy and stability.
When the deviation of feedback signal and giving signal <deviation limit, PID N regulation, keep

output stable.

When the deviation of feedback singnal and giving signal >deviation limit, PID regulates according

to deviation, update output

P10 PID Fault Detect Time 0.0~3200.0 s 0.0 N

P11 PID Fault Detected Value 0.0~100.0 % 10.0 N

Set P10 to 0. 0 for N fault inspection.

When PID feedback signal <P11 set PID fault inspection value, last P10set time, regard it as PID

regulation fault.

P12 PID Display Range 0.00~100.00 - 1.00 Y

A09 PID set value＝PID set value(%)*P12
A10 PID feedback value＝PID feedback value(%)*P12

If PID feedback 10V corresponding 4.0Mpa pressure, if need A09, A10 to display actual value,

only need to set P12 = 0.04.

5-9. Expanding parameters:E00-E23(0x0600-0x0617)

Code Description / LCD Setting Range Unit

E00 Load Type

General 0

Pump 1

Fan 2

Injection machine 3

Textile machine 4

Hoist machine 5

Kowtow Machine 6

belt conveyor 7

Variable frequency power 8

Multi-pumps constant pressure
water supply

9

Factory

Setting

- 0 N

Change

Limited

81

82

Section V Parameter Function Table

Section

V

o

Section V Parameter Function Table

Reserved 10

Reserved 11

Torque control 12

Voltage regulation power 13

Current regulation power 14

Extruding machine 15

Details, see Appendix IV.

Starting Pressure

E01

Deviation

0.0~100.0 % 10.0 Y

E02 Starting Delay Time 0.0~3200.0 s 5.0 Y

Feedback pressure <given pressure –starting pressure deviation.

Continuously exceed E02 start delay time, the inverter will restart under in the standby mode.This
parameter is used to prevent the inverter frequent start-stop.

E03 Stop Frequency 0~50.00 Hz 5.00 N

E04 Stop Delay Time 0.0~3200.0 s 5.0 Y

If the set frequency is less than or equal to E03, stop frequency exceeding E04 stop delay time, the
ac drive will change from running to the stop standby state.

The bigger E03 parameter setting, the easier for stop, E03 parameter is set to 0, indicating the stop

frequency and the start pressure control function is invalid.

E01, E02, E03,E04 mix are used to control system operation and water supply systems in the energy

-saving water pressure regulator.

For example:

Given pressure = 50%

Starting pressure deviation =10%, starting pressure = given pressure - starting pressure deviation=
40%

Topping frequency= 5Hz

pressure

set pressure
50

start pressure
10

frequency

upper frequency

stop pressure

lower frequency

High Pressure Arrival

E05

Va l ue

％

％

0

0

feedback pressure

actual frequency

H07

H08

time

time

0~100.0 % 90.0 Y

When feedback pressure reach and exceed the high pressure reached value of this parameter, the I/O

output terminal select 25, then it will output arrival signal.

Low Pressure Arribal

E06

Va l ue

0~100.0 % 10.0 Y

When feedback pressure less than the low pressure reached value of this parameter, the I / O output

83

terminal select 26, then it will output arrival signal.

1 bit

Timing
water
supply

invalid 0

Valid 1

Set

0

- 0000 Y

1

E07

Timing To Supply
Wat er

10 bit

Pressure
giving

according
to P03

Set
according t
H47~H54

Circle

100 bit

Timing
mode

Section V

mode

Single
circle

0

1

1000 bit Current timing step

1 bit: Timing water supply

0 Timing water supply function is invalid
1 Timing water supply function is valid

10 bit: pressure giving

0 the pressure given during regular pressure water supply is set according PID given value selecting
P03.
1 the pressure given during regular pressure water supply is set according the current corresponding
H47~H54 digital voltage given.

100 bit: timing mode

0 cycle mode

Start to time from start running, after it reached the setting time, the inverter will automatically
move to the next period of time set, after the end of a loop, it will automatically re-start from the
first paragraph 0, then cycle to run.

1 single cycle

Start to time from start running, after it reached the setting time, the inverter will automatically
move
to the next period of time set, after the end of a loop, the inverter will stop and wait for the next
running command.

1000 bit: the current regular time

When the water supply time set 0, it means cancel the water supply time setting of this period.

Current time Water supply time Pressure given

0 H18 H47

1 H19 H48

2 H20 H49

3 H21 H50

4 H22 H51

5 H23 H52

6 H24 H53

E08

7 H25 H54

Timing Shift
Alternation Time

0.0~3200.0 Hours 0.0 N

Timing Shift Alternation Time control the alternation ways and time of pump.

84

Section V Parameter Function Table

Section

V

When Timing Shift Alternation Time is set to 0.0 hour and cancel Timing Shift Alternation function.

When the Timing Shift Alternation Time between 0.1~3,200 , after corresponding time of the stable
running, in accordance with the principle of first stop for the one first started to control switch of pump.

First stop for the first pump started: When reduce pumps control, stop the first pump which started

first.

According to the principle of start first – stop first control, in order to ensure that every pump can

have the chance to run to prevent some pumps rusted as a result of no use for long , such as the need to

ensure that each operation of the pump can receive equal time, set Timing Shift Alternation Time.

Pump alternation order : E12 = 0x 0001

Starting State : No. 1 pump frequency, No. 2 pump frequency conversion and No. 3 pump stops ;

Rotation : No. 1 pump stops, No. 2 pump frequency, No. 3 pump frequency conversion ;

After the second rotation : No.1pump frequency conversion and No.2pump stops, No.3pump power
frequency.

Electromagnetic

E09

Switch Action Delay

Electromagnetic switch action delay time when set up a pump (drive motor) to switch from variable
frequency to industry frequency,or from industry frequency to variable frequency.This is to avoid inverter
output frequency meet with the AC power supply and occur short circuit caused because electromagnetic
switch action too slow.

Pumps Shift Judging

E10

Time

Set when output frequency converter arrives to upper frequency, until the judgment time of

increasing pumps (driving motor); or when output frequency converter arrives to lower frequency, until

the judgment time reducing pumps ( driving motor). Set the time long or short according to the speed of

pressure change, without oscillating range, the shorter the better.

Drives add or subtract pump control with E12 Water Supply Configuration

Add pump order No. 1 pump  No. 2 pump  No. 3 pump  No. 4 pump.

Reduce pump order No. 4 pump  No. 1 pump  No. 2 pump  No. 3 pump.

If the current : No. 1 pump frequency, No. 2 pump frequency, No. 3 pump convert frequency

after reduce pump: No. 1 pump frequency, No. 2 pump convert frequency,

after add pump: 1 pump frequency, No. 2 pump frequency, No. 4 pump convert frequency

after reduce pump :No. 1 pump frequency, No. 2 pump convert frequency,

after reduce pump: No. 1 pump frequency,

after add pump: No. 1 pump frequency, No. 3 pump convert frequency

after add pump: No. 3 pump frequency No. 4 pump convert frequency

after add pump: No. 1 pump frequency, No. 3 pump frequency No. 4 pump. frequency ,No. 2 pump
converter frequency,

Constant Pressure

E11

Water Supply

Configuration

0.000~10.000 s 0.500 Y

0~9999 s 5 Y

1 bit

Stop
mode

all pumps
slow down
stop

Va r ia b l e
frequency
pump stop

Free stop 2

Water supply
Pump stop

- 0000 N

0

1

3

Section V Parameter Function Table

Keep

Pumps

current

status

10 bit

100 bit

Section V

1000 bit

when
fault
occurs

Altern
ation
shift
mode

Pump
status
keep

situation

All-pumps
stop

Va r ia b l e
frequency to
working
frequency

Va r ia b l e
frequency to
stop

Keep status 0

Stop reset 1

0

1

0

1

1 bit : Stop mode

0 All slow down, all pumps in turn slowing down.

1 variable frequency pump stop:variable frequency pump stop running,variable frequency pump and

soft start pump under frequency keep running.

Stop power frequency pump,you need to use o36~o46parking command or keyboard input terminal

free multi - function keys MF1, MF2 set to 2 : Free Parking function.

2 Free stop, all pumps free stop

After free stop,E11 1000bit pump reset according to the order start and stop,but reorder according to

E12 multi - pumps configuration.

3 Water supply pump stops,only those constant pressure water supplying pumps stop,soft start pump

keep running under pump frequency.

Stop soft - starting pump, you need to use stop command of the soft star pump for o36 ~ o46 input

terminal or keyboard multi - function keys MF1, MF2 set to 2 : Free stop function.

10 bit: Treatment under fault pump states

0 maintain the status quo, when inverter failure, stop the current variable frequency pump operation

and other power - frequency operation of variable frequency pump and soft start pump maintain the

status quo

Fault occurs, if the following breakdown, select fault treatment according to failure action.

12 E.PId regulating fault

13 E.OHt Motor over heated fault

14 E.OL2 Motor over loading fault

15 E.PG PG fault

16 E.PHo Inverter output Phase lost

17 E.COA RS485 communication A fault

18 E.COb RS485 communication B fault

The feature only applies to the fault under the mode allowing fault runs. The fault is not allowed to

run, all stop.

1 All pump stop, when inverter failure, all pumps free stop.

100 Bit：Soft start switching mode

0 Convert frequency to power frequency, frequency control of the pump current increases the speed

85

86

Section V Parameter Function Table

Section

V

Section V Parameter Function Table

to the frequency, the rotation of the pump start and stop switch control or soft start pump

1 Frequency conversion to stop, stopped the current frequency conversion control of pump and

pump rotation switch or soft start pump start - stop control.

1000 Bit : pumping States maintain

0 Maintaining state, After multi pumps constant pressure water supply stop, keep the current

multipumps at the first start- first stop order.

1 Stopping reset , After multi pumps constant pressure water supply stop , E12 multipumps

configuration reorder multi - pump at the stop order.

Pump 1 invalid 0

Pump 1 variable
frequency to control

1 bit

pump

Pump 1 soft starts to
control pump

Pump 2 invalid 0

Pump 2 variable
frequency to control

10 bit

pump

Pump 2 soft starts to

Multi-pumps

E12

Configuration

100 bit

1000 bit

Under Multi-pump control mode, set the control mode of each pump.

E13 Multi-pumps Status

100 bit

control pump

Pump 3 invalid 0

Pump 3 variable
frequency to control
pump

Pump 3 soft starts to
control pump

Pump 4 invalid 0

Pump 4 variable
frequency to control
pump

Pump 4 soft starts to
control pump

Pump 1 stop 0

Pump 1 run in

1 bit

variable frequency

Pump 1 run in
working frequency

Pump 2 stop 0

Pump 2 run in

10 bit

variable frequency

Pump 2 run in
working frequency

Pump 3 stop 0

Pump 3 run in
variable frequency

87

1

2

1

2

- 0001 N

1

2

1

2

- 0000 N

1

2

1

2

1

Pump 3 run in
working frequency

Pump 4 stop 0

1000 bit

Under Multi-pump control mode, displays the status of each pump.

Section V

Soft Starting Pump

E14

Control

100 bit

1000 bit

Under Multi-pump control mode, set the control mode of each pump.

E15 User Parameter 0 0~9999

E16 User Parameter 1 0~9999 - 0 Y

E17 User Parameter 2

E18 User Parameter 3

E19 User Parameter 4

E20 User parameter 5

E21 User Parameter 6

E22 User Parameter 7

E23 User Parameter 8

※Please check appendix 4 for the detailed expanding parameter instruction.

0~9999

0~9999

0~9999

0~9999

0~9999

0~9999

0~9999

Pump 4 run in
variable frequency

Pump 4 run in
working frequency

Pump 1 soft-no
command

1 bit

Pump 1 soft-stop 1

Pump 1 soft-start 2

Pump 1 soft-no
command

10 bit

Pump 2 soft-stop 1

Pump 2 soft-start 2

Pump 1 soft-no
command

Pump 3 soft-stop 1

Pump 3 soft-start 2

Pump 1 soft-no
command

Pump 4 soft-stop 1

Pump 4 soft-start 2

2

1

2

0

0

- 0000 Y

0

0

-

- 0 Y

- 0 Y

- 0 Y

- 0 Y

- 0 Y

- 0 Y

- 0 Y

0 Y

5-10. Speed-loop parameter [SPD]:C00-C31(0x0700-0x071F)

Factory

Code Description / LCD Setting Range Unit

Filter Time Of

C00

Speed-loop

It defines the filter time of the speed-loop. The range is 0.01~100s.If the value is too great, the
control is stable but response is slow; if the value is too little, the system response is rapid but perhaps is
unstable. So it is necessary to consider the stability and the response speed at the same time when setting

2~200 ms 10 Y

88

Setting

Change

Limited

Section V Parameter Function Table

Section

V

Section V Parameter Function Table

the value.

Speed-loop Low Speed

C01

Ti

It defines the integral time of the speed-loop low speed. The range is 0.01~100.00s. If the integral
time is too great, response is slow and the control of external disturbing signal become bad; if the time is
too little, response is rapid, but perhaps brings the surge.

Speed-loop Low Speed

C02

Td

It defines the differential time of the speed-loop low speed segment and the range is 0.000~1.000s.
If the time is great enough, the surge which is caused by P action when difference occurring can
attenuate quickly. But too great, the surge will happen contrary. When the time is little, the attenuation
function is little too.

C03 Speed-loop Low Speed P

It defines the proportion gain of speed loop low speed segment.And the range is 0~1000%.If the
gain is great, the response is rapid, but too great, surge perhaps occurs; if the gain is too little, response is
slower.

Speed-loop Low Speed

C04

Shift Frequency

It defines low-speed loop switching frequency, the parameter and switching frequency at high-speed
optimize Speed-loop PID parameter.

Speed Loop High

C05

Speed Ti

It defines integration time of High-speed section of the speed loop.Range is0.01~100.00s.integration

time too large and unresponsive, external interference control variation becomes weak ; integration time

is small the reaction speed, oscillation occurs when it is too small.

Speed Loop High

C06

Speed Td

It defines the differential time of the speed-loop high speed segment and the range is 0.000~1.000s.
If the time is great enough, the surge which is caused by P action when difference occurring can
attenuate quickly. But too great, the surge will happen contrary. When the time is little, the attenuation
function is little too.

Speed Loop High

C07

Speed P

It defines the proportion gain of speed loop high-speed section, range from 0~1000%. Gain is large,
response speed, but too large gain will occur vibration; if the gain is small, the reaction lag.

Speed Loop And

C08

High-speed Switching
Frequency

It defines Integral time of speed loop high speed , the parameter and switching frequency at low -
speed optimize the speed-loop PID parameter.

Low-speed Slip Gain 0~200 % 100 Y

C09

Low-speed segment slip compensation gain

Low Speed Slip

C10

Switching Frequency

Low speed segment slip compensation switching frequency

High Speed Slip Gain 0~200 % 100 Y

C11

0.01~100.00

0.000~1.000

0~150

0.0~C08

0.01~100.00 s 0.50 Y

0.000~1.000 s 0.000 Y

0~150 % 75 Y

C04~max frequency Hz 30.00 Y

0~C12 Hz 5.00 Y

s 0.25 Y

s 0.000 Y

% 100 Y

Hz 7.00 Y

89

High speed segment slip compensation gain

High Speed Slip

C12

Switching Frequency

High speed segment slip compensation switching frequency

Upper Froward Torque 0.0~300.0 % 250.0 Y

C13

The parameter is a ratio，setting value is 100%. Responding to motor rated output torque.
Set forward torque mode through C15.
In speed control mode, it’s upper forward torque.
In torque control mode, it’s forward torque setting value.

C14 Upper Reverse Torque 0.0~300.0 % 250.0 Y

Section V

The parameter is a ratio，setting value is 100%.
Set reverse torque mode through C16.
In speed control mode, it’s upper reverse torque.
In torque control mode, it’s reverse torque setting value.

Forward

C15

Torque setting

mode

Reverse

C16

Torque setting
mode

C10~ max frequency Hz 30.00 Y

Setting

1 bit

mode

10 bit direction

Setting

1 bit

mode

Set by keyboard or

RS485

AI1 external analogy

giving

AI2 external analogy

giving

AI3 external analogy

giving

Keypad potentiometer

giving

Multi-step digital

voltage giving

Digital pulse set

Direction uncontrolled

Direction controlled

Set by keyboard or

RS485

AI1 external analogy

AI2 external analogy

giving

AI3 external analogy

giving

Keypad potentiometer

giving

Multi-step digital

0

1

2

3

- 0000 Y

4

5

6

0

1

- 0000 Y

0

1

2

3

4

5

90

Section V Parameter Function Table

Section

V

Section V Parameter Function Table

voltage giving

Digital pulse set

Direction uncontrolled

10 bit direction

C17 Torque Set Gain 0.0~300.0 % 200.0 Y

C15 1 bit：
C16 1 bit：

C15 10 bit: Direction Control
C16 10 bit: Direction Control

C18

can change speed or torque control through input terminal. After setting IP terminal change, keyboard set
invalid, only for query.

C19

Setting mode
Setting mode

0

1 AI1 external analog setting

2 AI2 external analog setting

3 AI3 external analog setting

4 Keyboard potentiometer setting As per keyboard potentiometer setting

5

6

While the unit digital of C15,C16 is 1—6, the torque up-limit of C13,C14 is for checking.

0: No control Direction

Direction is controlled by terminal or keyboard

1:Control Direction

Setting value of forward torque > setting value of reverse torque, forward direction.

Setting value of forward torque < setting value of reverse torque, reverse direction.

C13 upper forward torque =setting value percentage * C17 torque given gain.

C14 upper reverse torque =setting value percentage * C17 torque given gain.

Such as:

C15 forward torque setting way=4 keyboard potentiometer setting.

C16 reverse torque setting way=4 keyboard potentiometer setting.

Forward/reverse both can control direction, C15=0x14，C16=0x14.

Potentiometer corresponding setting value A48=-100%，A49=100%

Keyboard potentiometer set A47=100%，C17=200.0%

C13 forward torque up-limit=100%*200.0%=200.0%, control direction forward 200% torque

Keyboard potentiometer set A47=100%，C17=200.0%

C14 reverse torque up-limit=100%*200.0%=200.0%, control direction reverse 200% torque

Speed /Torque Control
Shift

F00 control method is to s select senseless vector control or sensor feedback close loop vector control

Upper speed

Setting mode

Set by keyboard or RS485

Multi segment digital voltage setting As per multi segment digital voltage setting

Digital Pulse Setting As per digital pulse setting

1 bit

Direction controlled

Responding to C13/C14

As per

As per

Speed control 0

Torque control 1

Separate

setting

keyboard or RS485

setting

mode

AI1 external analog 1

As per AI3 external analog setting

91

6

0

1

AI1 external analog setting

AI2 external analog setting

- 0 Y

- 0000 Y

0

setting

AI2 external analog

setting

AI3 external analog

setting

Keyboard

potentiometer setting

Multi-segment digital

voltage setting

Section V

10 bit

Selection

C20 Reverse Speed Limit 0.00~ Maximum frequency - 50.00 Y

While torque control, setting upper speed.

C19 1 bit: Separate setting mode

0

keyboard or RS485 setting

1 AI1 external analog setting

2 AI2 external analog setting

3 AI3 external analog setting

4 Keyboard potentiometer setting

5

Multi-step digital voltage setting As per Multi-step digital voltage setting

6

Digital Pulse Setting As per Digital Pulse Setting

While the unit digital of C19 is 1—6, the speed up-limit of C20 is for checking.

C19 10 bit; Select Speed Up-limit Setting Ways

0: separate setting, as per the selection of C19 Units digital.

1:setting frequency is according to S00,and affected by the following parameters.

F02 frequency main setting ways/F03 frequency secondary setting ways/F04 frequency setting

main and secondary.

Torque Acceleration

C21

Time

Torque Deceleration

C22

Time

C21, C22 torque acceleration time, turning moment deceleration torque control mode and effective.
Torque acceleration time, torque accelerated from 0 to 300 hours.
Torque speed, torque, from 300 down to 0.

Low Speed Exitation

C23

Excitation

Under low speed, compensate excitation quantity, increase torque feature, in case of meeting the

requirement, try to make it lower, could reduce the motor heating up caused by magnetic path full.

C24 Current Loop Ti 0~9999 ms 500 Y

0.0~200.0 s 1.0 Y

0.0~200.0 s 1.0 Y

0~100 % 30 Y

Digital Pulse Setting

C19 Unit bit setting

S00 Setting Frequency

As per C20 setting

As per AI1 external analog setting

As per AI2 external analog setting

As per AI3 external analog setting

As per keyboard potentiometer setting

92

2

3

4

5

6

0

1

Section V Parameter Function Table

Section

V

Section V Parameter Function Table

Define the current loop integral time. When integral time is too long, response is inactive; the

ability to control external jamming becomes weak. When integral time is short, response is fast, if too

short, vibration will occur.

C25 Current Loop P 0~1000 % 100 Y

Define current loop proportion gain, When select big gain, response fast, but too big will occur

vibration. when select low gain, response lag.

C26 PG Electronic Gear A 1~5000 - 1 Y

C27 PG Electronic Gear B 1~5000 - 1 Y

When encoder and motor is in different shaft, can calculate current motor speed according to

encoder and gear ratio.

Electronic gear A for denominator, B for molecule.

C28 PG Pulse 300~9999 - 2500 N

PG pulse quantity used, set value is the pulse quantity when motor rotates for a circle.

N PG break protection 0

C29 Action When PG Break

Set the brake method when detect PG break.
0 : N PG break protection
1 : Warning and keeping running.
2 : Warning and deceleration stop.

3 : Warning and free stop.

C30 PG Rotating Direction

phase A

phase B

phase A is forward

Encoder rotating direction, refer to the motor forward direction
0 : When motor forward, phase A leads, set C27= 0
1 : When motor forward, phase B leads, set C27= 1

Note: above parameters are valid when with encoder(PG), need to layout PG card. If needed, please

contact our company.

PG Dropped

C31

Inspection Time

PG feedback signal is 0, exceed C31 set time, system reports PG dropped fault. Set speed to 0, or

sert C31 to 0, don’t check PG dropped fault.

Warning and keeping running 1

Warning and deceleration stop.

Warning and free stop. 3

When motor forward, phase A
leads

When motor forward, phase A
leads

phase A

phase B

phase B is forward

0.0~10.0 s 1.0 N

- 3 Y

2

0

- 0 Y

1

5-11. Motor parameter [MOT]:b00-b22(0x0800-0x0816)

Factory

Code Description / LCD Setting Range Unit

Motor 1 Rated

b00

Frequency

0.00~Maximum frequency Hz 50.00 Y

93

Setting

Change

Limited

b01 Motor 1 Rated Current y09*(50%~100%) A ★

b02 Motor 1 Rated Voltage 100~1140 V ★

b03 Motor 1 Pole-pairs 1~8 - 2

b04 Motor 1 Rated Speed 500~5000 rpm 1480

b00~b04 are the motor’s nameplate parameters which touch the precision.Set the parameters

according to the motor ’s nameplate.

b00 ~ b04 motor nameplate in parameters, it is necessary to re-calculate motor parameters by using

b11.

Excellent vector control performance requires exact motor parameters. Exact parameters are base

on the correct setting of motor’s rated parameters.

Section V

To assure the control performance, please match the right motor as per the inverter’s standard,

motor rated currents limited between 30%~120% of inverter rated current.

The rated current can be set, but can’t be more than the rated current of the inverter. The parameter

confirms the OL protection capability of the motor and energy-saving running.

To prevent self-cooled motor form overheat when running in a low speed, and the motor capacity

change when motor character change little, the user can correct the parameter to protect the motor.

The number of motor pole pairs, such as the four pole motor, the number of pole pairs is set to 2

Motor 1 N Load

b05

Current

Motor 1 Stator

b06

Resistance

Motor 1 Rotor

b07

Resistance

Motor 1 Stator

b08

Inductance

Motor 1 Mutual

b09

Inductance

b05~b09 can by input by motor actual parameters value, also can define motor parameter by b11
parameter measure function.and save automatically. If know the correct motor parameter, can input by
hand

When b11 is 1, 2, 3, the system calculates and measuresautomatically.

b05~b09 is the motor’s basic electric parameters, these parameters is essential to achieve vector
control calculation.

b10 Motor Selection

The system can select any group motor parameters.

Motor parameter measurements modify and save to corresponding motor parameter area
automatically.

Motor Parameter

b11

Measurement

Set whether the measurement of electrical parameters in order to b10 motors choose motor 1 as an
example.

0 : N measurement

1 : Calculate by label data

According to the motor nameplate parameters b00 ~ b04 , automatic calculation b05 ~ b09 and

0.0~b01 A ★ Y

0.000~30.000 ohm ★

0.000~30.000 ohm ★

0.0~3200.0 mH ★

0.0~3200.0 mH ★

Motor 1 0

Motor 2 1

N measurement 0

calculate by label data 1

inverter static measurement

inverter rotation measurement 3

- 0 N

- 0 N

2

94

Y

Y

Y

Y

Y

Y

Y

Y

Section V Parameter Function Table

Section

V

Section V Parameter Function Table

other electrical parameters,the advantage does not require power-on self - tuning,suitable for general

- purpose Y series of four pole motor, the other type motor can be adjusted based on this parameter.
2 : Inverter static measurement
3 : If the motor parameters can not be measured without load,you can choose static frequency converter

measurement. Make sure that motor in a static status ,after static measurement, it can be manually
adjusted some parameters, optimal control.

4 : The b11 is set to 2, the inverter automatically start parameter determination.

Keyboard figures area show "-RUN": waiting to run the command, start the measurement.
Keyboard figures area show "CAL1", inverter without output.
Keyboard figures area show "CAL2", inverter with output, static state.
Keyboard figures area show "-END": measuring ends.
Keyboard figures area show "E. CAL": the measurement process errors.
Process can be measured through the STOP key to stop.

3 : Inverter rotation measurement

Motor can be measured without load, can choose the rotation measurement. Measurements started,
make sure the motor is static.
Static measurement converter, the output DC voltage, pay attention to safety.
The b11 is set to 3, the inverter automatically start parameter determination.
Keyboard figures show that the regional show "-RUN": waiting to run the command, start the
measurement.

Keyboard figures area show "CAL1", "CAL3": N output inverter.
Keyboard figures area show "CAL2", inverter with output, under static state.
Keyboard figures area show "CAL4", inverter with output, the motor forward in high-speed.
Keyboard figures area show "-END": measuring the end.

Keyboard figures area show "E. CAL": the measurement process errors.
Process ca

n be measured through the STOP key to stop.

Set this parameter,the motor parameters will be determined dynamically.Be sure the motor is

without load (N-load operation).

Before setting,be sure to run well prepared,the motor will run in high speed during the measurement

Measurement is completed, b11 return to 0. The measured parameters will select parameters on the

base of b10 motor parameters which is automatically saved to the b05 ~ b09 or b18 ~ b22.

Note: Before auto-measure the motor parameter, must input motor rated parameter b00~b04or

b13~17 correctly

Please regulate accelerating and deceleration time or torque increasing parameter, if there is over -

current or over voltage faults while auto- measurement.

When automatic regulation, motor should be in stop status.

Vector Control initial

b12

Inspection R1

Motor 2 Rated

b13

Frequency

b14 Motor 2 Rated Current y09*(50%~100%) A ★ Y

b15 Motor 2 Rated Voltage 100~1140 V ★ Y

b16 Motor 2 Pole Pairs 1~8 - 2 Y

b17 Motor 2 Rated Speed 500~5000 rpm 1480 Y

b18 Motor 2 N Load Current 0.0~b14 A ★ Y

Motor 2 Stator

b19

Resistance

b20 Motor 2 Rotator 0.000~30.000 ohm ★ Y

Not inspection R1 0

Inspection R1 1

0.00~Maxmum frequency Hz 50.00 Y

0.000~30.000 ohm ★ Y

- 0 N

95

Resistance

Motor 2 Stator

b21

Inductance

Motor 2 Mutual

b22

Inductance

The 2nd group motor parameters can be set by system. The definition is same with group 1.

0.0~3200.0 mH ★ Y

0.0~3200.0 mH ★ Y

5-12. System parameter [SYS]:y00-y17(0x0900-0x0911)

Factory

Code Description / LCD Setting Range Unit

No action 0

Section V

Reset System

y00

Parameter

0 : No action
1 : Reset system parameter with keyboard storage 1
2 : Reset system parameter with keyboard storage 2
3 : Reset system parameter with keyboard storage 3
4 : Reset system parameter with keyboard storage 4
5 : Reset system parameter with factory set value

When this parameter set valid, all the function parameter reset to factory setting. The parameters

without factory setting will save the previous setting value.

Parameter Upload To

y01

Keyboard

0 : No action;

1 : Reset system parameter with keyboard memory area1;

2 : Reset system parameter with keyboard memory area2;

3 : Reset system parameter with keyboard memory area3;

4 : Reset system parameter with keyboard memory area4;

5 : Clear up keyboard memory area 1, 2, 3, 4

y02 Lastest Fault record Lastest fault record number mH 0 Y

y03 Fault Record 1

Reset system parameter with
keyboard storage1

Reset system parameter with
keyboard storage 2

Reset system parameter with
keyboard storage 3

Reset system parameter with
keyboard storage 4

Reset system parameter with
factory set value

No action 0

Reset system parameter with
keyboard memory area1

Reset system parameter with
keyboard memory area2

Reset system parameter with
keyboard memory area3

Reset system parameter with
keyboard memory area4

Clear up keyboard memory
area 1, 2, 3, 4

Press [PRG]and [/] key the - 0 Y

1

2

- 0 N

3

4

5

1

2

- 0 N

3

4

5

96

Setting

Change

Limited

Section V Parameter Function Table

Section

V

Section V Parameter Function Table

y04 Fault Record 2

y05 Fault Record 3

frequency, crrent and running status of
fault time can be known.

y06 Fault Record 4

y07 Fault Record 5

These parameters register fault which happen in the last several times, and can inquire about the

value of monitor object at the time of fault by ‘PRG’ and “plus or minus” key.

The monitor object of fault state:
0: Fault type
The fault code is expressed as following:

Serial number LED display

Fault

0 E.OCP System is disturbed or impacted by instant over current

1 Reserved

2 E.OC3 Over current or over voltage signal from drive circuit.

3 Reversed

4 E.OU Over voltage

5 E.LU Under voltage

6 E.OL Over load

7 E.UL Under load warm

8 E.PHI Power input Phase loss

9 E.EEP EEPROM error

10 E.ntC Over heat

11 E.dAt Time limit fault

12 E.Set External fault

13 Reserved

14 Reserved

15 Reserved

16 E.PID PID regulate fault

17 E. OHt Motor over heat fault

18 E.OL2 Motor over load fault

19 E.PG PG fault

20 E.Pho Inverter output phase-lost

21 E.COA RS485 communication terminal A failure

22 E.Cob RS485 communication terminal B failure

23 E.CAL

Parameter identification problems.

1: set frequency at the time of fault

The output frequency of the inverter at the time of fault

2: output frequency at the time of fault

The output frequency of the inverter at the time of fault

3: output current at the time of fault

The actual output current at the time of fault

4: output DC voltage at the time of fault

The actual output voltage at the time of fault

5: Running state at the time of fault

The running state at the time of fault
LEDdisplay is below:

the first LED tthhte The second LED The third LED the fourth LED

forward

F

command

Reverse

R

command

Section V

S Stop command S Stop status

6: running time at the time of fault

F forward status A accelerating

R Reverse status D deccelerating

separator

E

running in a

even speed

S Stop status

The running time at the time of fault

7: Inverter IGBT temperature at the time of fault

Inverter IGBT temperature

y08 Fault Record Reset

No action 0

Reset 1

- 0 Y

0 : No action, the fault records retains

1 : the fault records resets

y09 Rated Output Current 0.1~1000.0 A ★ N

Inverter rated output current.

y10 Rated Input Voltage 100~1140 V ★ N

The rated input voltage of the inverter. It would be set as per inverter input voltage level before

leaving factory.

80 0 3

y11 Product Series

Family

code

Product

serial

Input oltage

grade 1

- ★ N

Product series (set according to family code/product serial/voltage grade)

80 0 3

family code
80

：

8000 serial

：

8100 serial

81

series number

0: Flow load (F)

:

General load (G)

1

2: Middle load (M)
3: Heavy load (H)
6: TEXDRIVE (S)
7: WINDLASS (T)
8:JETDRIVE (Z)

y12 Software Version - - - N

A:

official version

B:

specialized version

C:

beta version

version number

y13 Product Date-- Year YYYY - - N

input voltage level

1: single phase 220V

2: three phase 220V
3: three phase 380V
4: three phase 460V
5: three phase 575V
6: three phase 660V
9: three phase 1140V

97

98

Section V Parameter Function Table

Section

V

Product Date

y14

-Month/Day

MMDD - - N

0~9999 Set range

y15 User Decode Input

Record password
wrongly input times

Display info

- - Y

In the state of locked parameter,LED displays the times of error input. There are three input limit,if
input is wrong in continuous three times , the systems will prohibit input of the password . It can prevent
testing password in an illegal way, and need restart the machine to input again.

Once the input is right in any time during three times input limit, the parameter is unlocked.

0~9999 Set range

No password or

y16 User password key-in

decode input is
correct

code

Display info

- - Y

Parameter lock-in code

The parameter sets the password , and the range is 0 ~ 9999 . After setting the password , parameter
locks and keyboard displays “code”; if the password is unlocked or password input is right, the keyboard
will display “deco”.

Set password to 0, reset user password set, after re-electrify status is decode.

Corresponding parameter group

y17

Parameter Group
Protection

protection after set password
Set to 0: change is not allowed
Set to 1: change is allowed

98

22222222

22

76543210

89

01234567

F group

group

A
o group
H group
U group
P group
E group
C group
b group
y group

- 0000 Y

Section VI. Fault Diagnosis & Solutions

6-1. Problems and solutions

Problems Possible causes Solutions

Keyboard

can not
control

Potentiomet

er can’t

regulate

speed

Section VI

The motor

Does not

rotate

Ove rcurrent

E.OC

Over load

E.OL

Over

voltage

E.OU

Running control mode setting is
wrong

Frequency setting is wrong

Control mode setting is wrong

Frequency setting is wrong

LED monitor dislay fault

No voltage in terminals DC+1
and DC+2

U, V or W terminals produce No
output or abnormal output.

Check F05

Check F03、F04

Check F05

Check F03、F04

Press RESET or terminal for fault reset, learn

and fix the fault according to the fault info

Check the voltage at R, S or T and charging
circuit.

Check the control mode and frequency

parameter. Check the terminal condition if it

is operated by an external terminal.

Re-start after powering down or
free run

Too much load on the motor

Fault display E.OCP

Remember the set operating state.

Check the load condtion, and confirm the

model selection is right

System is disturbed or instant over current

Motor over current, protect action when

Fault display E.OC3

motor actual current is 3 times over than the
motor rated current

Over current during acceleration

Over current during deceleration

During starting, the
low-frequency jitter over-current

Over current during operation

Over current during starting or
operation sometime

Disturbance

Reset or adjust F09, F20, F21.

Reset or adjust F10, F22, F23.

Modify F06 setting

Check the load change and eliminate it.

Check if there is slight short circuit or
grounding.
Check the earthing wire, screened cable
grounding and terminals.

Lower the load.or enlarge b04, b14 in the

Too much load

allowable load range or enlarge A24 to raise

the thermal protection level.

Inappropriate parameter is set

Modify b04、b14 in case of the motor over

-load allowed

Check voltage is right or not.

Power voltage exceeds the limit

Frequency inverter rated voltage setting is Y

or N.

Too fast deceleration Modify F10.

99

100

Section VI Fault Diagnosis & Solutions

The load has too much inertia

of frequency converter, or add a braking
resistor.
Checking voltage is normal or not.

Reduce the load inertia, or raise the capacity

Low voltage

E.LU

Too low power voltage

Power off transiently

The line has too small capacity or
great rush current exists on the

Frequency inverter rated voltage setting is Y
or N.
Add options of capacitor boxes.

Make renovation on power supply system.

lines.

Too high ambient temperature Improve ambient conditions

Over heat

E.OHt

Cooling fans do not work.

The carrier frequency is too high

Check A27, reduce fan starting

tamperaturer(when there is fan control)

Check the setting value of function F16

Note:

※ Switch off the power supply, and do not touch the PCBs and any parts inside in five minutes after

the charging indicator light (！CHARGE) goes off. Ensure the capacitance has been discharged
completely by measuring with the instrument before work inside. Otherwise, there is a danger of
electric shock.

※ Do not touch the PCB or IGBT and other internal parts unless actions have been taken to prevent

the static electricity. If not, the components may be damaged.

Section VII Standard Specifications

7-1. Specification

7-1-1. PI8000 Specification

Light Load F Standard Load G Medium Load M Heavy Load

Inverter

type

PF

kW

IF

PG

IG A PM

A

kW

IM A PH

kW

3 phase voltage 380V 50/60Hz

PI80003 15 32 11 25 7.5 16 8N2

PI80003 18.5 38 15 32 11 25 7.5 16 8N2

PI80003 22 45 18.5 38 15 32 11 25 8N3

PI80003 30 60 22 45 18.5 38 15 32 8N3

PI80003 37 75 30 60 22 45 18.5 38 8N4

Section VI.

PI80003 45 90 37 75 30 60 22 45 8N4

Section VII

PI80003 55 110 45 90 37 75 30 60 8N5

PI80003 75 150 55 110 45 90 37 75 8N5

PI80003 93 170 75 150 55 110 45 90 8N6

PI80003 110 210 93 170 75 150 55 110 8N6

PI80003 132 250 110 210 93 170 75 150 8N7

PI80003 160 300 132 250 110 210 93 170 8N7

PI80003 187 340 160 300 132 250 110 210 8N8

PI80003 200 380 187 340 160 300 132 250 8N8

PI80003 220 415 200 380 187 340 160 300 8N9

PI80003 250 470 220 415 200 380 187 340 8N9

PI80003 280 520 250 470 220 415 200 380 8N9

PI80003 200 380 200 380 187 340 160 300 8NA

PI80003 220 415 220 415 200 380 187 340 8NA

PI80003 250 470 250 470 220 415 220 380 8NA

PI80003 315 600 280 520 250 470 220 415 8NB

PI80003 355 640 315 600 280 520 250 470

PI80003 400 690 355 640 315 600

PI80003 450 740 400 690

kW

H

IH

Structure

item

A

8NB

8NB

8NB

101

102

Section VII Standard Specifications

Section

VI
I

Section VII Standard Specifications

7-1-2. PI8100 Specification

Light Load F Standard Load G Medium

Inverter type

Single phase voltage 220V 50/60Hz

PI81001 0.75 4 0.4 2.5 7N2

PI81001 1.5 7 0.75 4 0.4 2.5 7N2

PI81001 1.5 7 0.75 4 0.4 2.5 7N2

PI81001 2.2 10 2.2 10 1.5 7 0.75 4 7N3

PI81001 4 16 4 16 2.2 10 1.5 7 7N3

PI81001 5.5 20 5.5 20 4 16 2.2 10 7N4

3 phase voltage 220V 50/60Hz

PI81002 0.75 4 0.4 2.5 7N2

PI81002 1.5 7 0.75 4 0.4 2.5 7N2

PI81002 1.5 7 0.75 4 0.4 2.5 7N2

PI81002 2.2 10 2.2 10 1.5 7 0.75 4 7N3

PI81002 4 16 4 16 2.2 10 1.5 7 7N3

PI81002 5.5 20 5.5 20 4 16 2.2 10 7N4

3 phase voltage 380V 50/60Hz

PI81003 0.75 2.5 0.75 2.5 0.75 2.5 0.75 2.5 7N2

PI81003 1.5 3.7 1.5 3.7 1.5 3.7 1.5 3.7 7N2

PI81003 2.2 5 2.2 5 2.2 5 2.2 5 7N2

PI81003 4 8.5 4 8.5 4 8.5 4 8.5 7N3

PI81003 5.5 13 5.5 13 5.5 13 7N3

PI81003 7.5 16 7.5 16 7.5 16 5.5 13 7N4

PI81003 11 25 7N4

PF

kW

IF A PG

kW

Load M

IG A PZ

kW

Heavy Load

IZ A PH

kW

H

IH

A

Structure

item

7-1-3. Table of rated current for different specifications

G/F/H/S/Z/T/M

Votage

Power

(kW)

220V

1Ф

Current

(A)

220V

(240V)

Current

(A)

380V

(415V)

Current

(A)

460V

(440V)

Current

(A)

575V 660V

Current

(A)

Current

(A)

0.4 2.5 2.5 - - - -

0.75 4 4 2.5 2.5 - -

1.5 7 7 3.7 3.7 - -

2.2 10 10 5 5 - -

4 16 16 8.5 8 - -

5.5 - 20 13 11 - -

7.5 - 30 16 15 - -

11 - 42 25 22 17 15

15 - 55 32 27 22 18

Section VII

18.5 - 70 38 34 26 22

22 - 80 45 40 33 28

30 - 110 60 55 41 35

37 - 130 75 65 52 45

45 - 160 90 80 62 52

55 - 200 110 100 76 63

75 - 260 150 130 104 86

93 - 320 170 147 117 98

110 - 380 210 180 145 121

132 - 420 250 216 173 150

160 - 550 300 259 207 175

187 - 600 340 300 230 198

200 - 660 380 328 263 218

220 - 720 415 358 287 240

250 - - 470 400 325 270

280 - - 520 449 360 330

315 - - 600 516 415 345

355 - - 640 570 430 370

400 - - 690 650 520 430

450 - - 740 700 600 490

500 - - 860 800 650 540

103

104

Section VII Standard Specifications

Section

VI
I

Section VII Standard Specifications

7-2. Standard specification

Items Specifications

Voltage and

Power

Control

Running

frequency

Allowable
Fluctuation range

Control system

Output frequency

control method

Start torque

speed adjustable
range

Speed stabilizing
precision

waveform produce
methods

Auto torque boost
function

Accelerate
/decelerate control

Long running time
control

frequency setting
accuracy

frequency accuracy

V/F curve mode

Over load
capability

slip compensation

Running method Keyboard/terminal/communication

Starting signal

Single-phase 200~240V, 50/60Hz

Three-phase 200~240V, 50/60Hz

Three-phase 380~415V, 50/60Hz

Three-phase 440~460V, 50/60Hz

Three-phase 575V, 50/60Hz

Three-phase 660V, 50/60Hz

Three-phase 1140V, 50/60H

voltage: ±15% frequency: ±5%

high performance vector control inverter based on 32 bit DSP

G/F/Z/S/T/M type: 0.00~800.0Hz, maxmum frequency can be set
between 10.00 and 800.0Hz
H type: 0.00~2000.0Hz, maxmum frequency can be set between

10.00 and 2000.0Hz

V/Fcontrol

0.50Hz 180% 0.25Hz 180% 0.00Hz 180%

1: 100 1: 200 1: 2000

±0.5% ±0.2% ±0.02%

Asynchronous space vector PWM, N-class sub-synchronous space
vector PWM, two-phase optimization of space vector PWM.

Achieve low frequency (1Hz) and high output torque control under
V.F control mode.

Sub-set S curve acceleration and deceleration mode, maximum
acceleration and deceleration time is 3200 days

16 segments speed run, maximum running time is 3200 days

Digit: 0.01Hz(below 300Hz), 0.1Hz(above 300Hz);
alalogue: 1% of maxmum frequency

Speed control tolerance 0.01%(25℃±10℃).

Linear, 1.2 times the power, 1.7 times the power, 2 times power,
user-set 8 V / F Curve.

G / S type: 150% rated current -1 minute, rated current 200% -0.1
second;
F: rated current 120% -1 minute 150% of rated current -0.1
second;
Z / M / T type: rated current 180% -1 minute 250% rated current

-0.1 second;
H: rated current 250% -1 minute 300% rated current -0.1 second.

V / F control can automatically compensate for deterioration.

Forward, reverse, jog (parameter control direction), forward jog,
and reverse jog.

Sensorless vector
control

Sensor close loop
vector control

105

Emergency stop Interrupt controller output.

fault reset

Running status

DC brake

Inverter protection

IGBT temperature
desplay

Protection

Section VII

Keyboard

Commu-

Inverter fan control The fan starting temperature can be set(optional)

Instant power-down
re-start

Speed starting track
method

Parameter
protection function

8 way switch input

3 way analog inputs

IO

2 way anolog
output

Virtual terminal
function

Frequency set

Keyboard cable 8-core cable, in line with EIA T568A, EIA T568B standards.

Double keyboard
port

Double and multi
function keys

4-parameter storages

Running info At most display 3 monitoring parameters. Select by A00, A01, A02

Fault info

Double RS485 port Rs485 port and an optional keyboard completely isolated RS485

When the protection function is active, you can automatically or
manually reset the fault condition.

Motor status display, stop, acceleration and deceleration, constant
speed, the program running.

Built-in PID regulator brake current flow in the premise, however,
to ensure adequate braking torque.

Overvoltage protection, undervoltage protection, overcurrent
protection, overload protection, over-temperature protection, over
the loss of speed protection, over-voltage stall protection, phase
protection (optional), external fault, communication error, PID
feedback signal abnormalities, PG failure

Display current IGBT temperature

Less than 15 milliseconds: continuous operation.
Greater than 15 milliseconds: Automatic detection of motor speed,
instantaneous power-down re-start.

automatically track motor speed when inverter starts

Protect inverter parameters by setting the password and decoding

Can be customized into 68 kinds of functions, to achieve forward,
reverse, forward jog, and reverse jog, emergency stop, reset, speed,
acceleration speed, run-time switch, and pulse counting.

Can be defined as a switch input;
To allow for maximum input range-10V ~ +10V, 0 ~ 20mA

Can achieve output range 0 ~ +10V, 0 ~ 20mA

Can be set to a virtual terminal, using communication or keyboard
IO port, and with the IO port status display.

In 6 main ways + to 7 kinds of auxiliary to the way of the keyboard,
three way analog input, pulse input, digital potentiometers.

Supports dual-keyboard, synchronous control, independently of
each other.

MF1, MF2 can be customized as addition and subtraction, forward,
reverse, forward jog, and reverse jog, emergency stop, rise and fall,
and other 9 kinds of ways.

Control panel can be realized four groups of inverter parameters of
upload, download, with manufacturer password to reset factory
setting.

Store 5 groups error messages at most, you can check the type of
failure time when failure occurrs, set frequency, output frequency,
output voltage, output current, running state, running time, IGBT
temperature.

106

Section VII Standard Specifications

Section

VI
I

Section VII Standard Specifications

nication

Speed

PID

Motor

Environ-

ment

communication module.

CAN BUS Can select can-bus module.

16-segment speed

8-segment running
time

8 segment
acceleration speed

Seven-Segment
Speed
Configuration

PID feedback signal

PID giving signal

2 goups of motor
parameters

3 identification
method

5 name plate
parameters

5 indentification
parameters

Environment
temperature

Store temperature

Environment
humidity

Height·vibration

At most 16 segments can be set (use multi-functional terminal to
shift or program runs).

At most8segment running time can be set(multi-functional terminal
can be used to shift)

At most 8 acceleration speed(can use the multi-functional terminal
to switch).

At most 7 segment speed configuration can be set
(multi-functional terminal can be used to switch).

Six kinds of ways, keyboard, three way analog input, pulse input,
digital potentiometers.

Six kinds of ways, keyboard, three wayl analog input, pulse input,
digital potentiometers.

With the motor parameters, parameter can be selected, parameter
identification automatic storage.

Name plate calculation, static measurement, rotation measurements.

Rated frequency, rated current, rated voltage, the number of pole
pairs, rated speed.

N-load current, stator resistance, rotor resistance, stator inductance,
mutual inductance.

-10℃ ~ 40℃, 40 ~ 50℃ derating between the use is increased by
1 ℃, rated output current decrease of 1%.

-40℃~+70℃

5~ 95 %, No condensation

0 ~ 2000 meters, 1000 meters above derating use, increased by 100
m, rated input decreased%

Mounted vertically inside the control cabinet with good ventilation,

Application
location

do not allow the level , or other installation method . The cooling
medium is air. Installed in the absence of direct sunlight, N dust, N
corrosive and explosive gas, N oil mist, N steam, N drip
environment

Cooling method Forced air cooling and natural air cooling.

7-3. Sharp Size

7-3-1. PI8000 family (3 phase voltage 380~415V, 50/60Hz)

1. 8N2~8N9

Section VII

1) 8N2

Typ e

F 15~18.5

G 11~15

M 7.5~11

H 7.5

2) 8N3

Typ e

F 22~30

G 18.5~22

M 15~18.5

H 11~15

3) 8N4

Typ e

F 37~45

G 30~37

d

Power

(kW)

Power

(kW)

Power

(kW)

W

b

a

L

Structure

item

Shape Installation dimension

L W H a b d

8N2 380 220 230 360 135 Ø10

Structure

item

Shape Installation dimension

L W H a b d

8N3 460 280 245 440 160 Ø10

Structure

item

Shape Installation dimension

L W H a b d

8N4 500 300 270 480 200 Ø10

H

107

108

Section VII Standard Specifications

Section

VI
I

Section VII Standard Specifications

4) 8N5

Typ e

M 37~45

5) 8N6

Typ e

M 55~75

6) 8N7

Typ e

M 93~110

M 22~30

H 18.5~22

Power

(kW)

F 55~75

G 45~55

H 30~37

Power

(kW)

F 93~170

G 75~93

H 45~55

Power

(kW)

F 132~160

G 110~132

H 75~93

Structure

item

Shape Installation dimension

L W H a b d

8N5 630 360 297 610 200 Ø10

Structure

item

Shape Installation dimension

L W H a b d

8N6 700 400 297 680 200 Ø10

Structure

item

Shape Installation dimension

L W H a b d

8N7 750 475 320 730 260 Ø10

2. 8NA

Muro di sostegno del
foro di montaggio

Section VII

7) 8N8

Typ e

M 132~160

8) 8N9

Power

(kW)

F 187~200

G 160~187

H 110~132

Typ e

Power

(kW)

F 220~250~280

G 200~220~250

M 187~200~220

H 160~187~200

Structure

item

Shape Installation dimension

L W H a b d

8N8 850 500 320 830 260 Ø10

Structure

item

Shape Installation dimension

L W H a b d

8N9 1000 600 380 940 370 Ø14

109

Typ e

a

Power

(kW)

Structure

item

Shape Installation dimension

L W H a b d

F 200~220~250

G 200~220~250

M 187~200~220

8NA 1540 515 443 465 367 Ø13

H 160~187~220

110

Section VII Standard Specifications

Section

VI
I

Section VII Standard Specifications

3. 8NB

L

bottom board

b

W

d

a

Typ e

F 315~355~400~450

G 280~315~355~400

M 250~280~315

H 220~250

Power

(kW)

bottom entry

Structure

item

H

Shape Installation dimension

L W H a b d

back

8NB 1700 850 492 640 260 Ø13

entry

7-3-2. PI8100 Family

1. 7N2~7N4

1) 7N2

DIGITAL PANEL

+

-

PRG

SET

FWD REV

S00

设定频率

0.00 0.0

S01

实际频率

S10 PID

反馈值

ESC STOP/RESET

ALARM

Hz

%

°C

A

s

V

-

E

N
T
E
R

+

FWDMF2MF1

Section VII

Power type Ty pe

Power

(kW)

F 0.75~1.5

Single phase

220V

G 0.4~1.5

M 0.4~0.75

H 0.4

F 0.75~1.5

3 phase

220V

G 0.4~1.5

M 0.4~0.75

H 0.4

F 0.75~1.5~2.2

3 phase

380V

G 0.75~2.2

M 0.75~2.2

H 0.75~2.2

111

112

Section VII Standard Specifications

Section

VI
I

Section VII Standard Specifications

2) 7N3

DIGITAL PANEL

+

-

S00 设定频率

0.00 0.0

S01 实际频率
S10 PID反馈值

PRG

SET

FWD REV

ALARM

ESC STOP/RESET

Hz

%

°C

A

s

V

-

E
N
T

E
R

+

FWDMF2MF1

Power type Typ e

Single phase

220V

3 phase

220V

3 phase

380V

Power

(kW)

F 2.2~4

G 2.2~4

M 1.5~2.2

H 0.75~1.5

F 2.2~4

G 2.2~4

M 1.5~2.2

H 0.75~1.5

F 4~5.5

G 4~5.5

M 4~5.5

H 4

3) 7N4

DIGITAL PANEL

ALARM

FWD REV

设定频率

实际频率

反馈值

ESC ST OP/RESET

Hz

%

°C

A

s

V

-

E
N

T
E
R

+

FWDMF2MF1

+

-

S00

0.00 0.0

S01
S10 PID

PRG

SET

Section VII

Power type Ty pe

Power

(kW)

F 5.5

Single phase

220V

G 5.5

M 4

H 2.2

F 5.5

3 phase

220V

G 5.5

M 4

H 2.2

F 7.5~11

3 phase

380V

G 7.5

M 7.5

H 5.5

113

114

Section VII Standard Specifications

Section

VI
I

Section VII Standard Specifications

7-3-3. Keyboard size

JP6C8000:

DIGITAL PANEL

FWD REV ALARM

+

-

PRG

MF1 MF2 FWD

SET

ESC

JP6E8000:

STOP/RESET

JP6D8000 the dimension of keyboard rabbet:

Hz

%

℃

A

s

V

-

E
N
T
E
R

+

Section VII

the dimension of aperture for installing keyboard in panel：

（75.5±0.1）*（122.5±0.1）

DIGITAL PANEL

FWD REV ALARM

+

-

PRG

SET

MF1 MF2 FWD

ESC

STOP/RESET

Hz

%

℃

A

s

V

-

E

N
T
E

R

+

115

116

Section VIII Maintenance

Section VIII. Maintenance

8-1. Inspection and Maintenance

Under normal working conditions, in addition to daily inspection, the frequency converter should be
subject to regular inspection (for example inspection for overhaul or as specified but at an interval of six
months at most). Please refer to the following table in order to prevent faults.

Check

time

D R

 Display

 

 Body





plug-in-parts at random. Otherwise, the unit will not operate normally, or can not enter the mode of fault
display, or causes faults of components or even parts of the main switch components IGBT module is
damaged.

the measuring is performed with different instruments. It is recommended that the input voltage be
measured with pointer-type voltmeter, output voltage with rectification voltmeter, input and output
current with tong-test ammeter, and power with electrically-driven wattmeter.

8-2. Periodically-Replaced Parts

maintenance and inspection, all the parts suffering long-term mechanical wear should be replaced at a
regular interval, which includes all cooling fans and the filtering capacitors of main circuits for energy
buffer and interchange and PCBs. For continuous use under normal conditions, these parts can be
replaced according to the following table and the operating environment, loads and the current state of
frequency converter.

Check

point

Cooling

system

Input/

output

terminal

Main

circuit

Check item Check to be done Method Criterion

LED and OLED

display

Fan

Surrounding

conditions

Voltage

Overall conditions

Electrolytic
capacitance

Current-conducting

leads or blocks

Ter mi na ls

If there is any
abnormal display

If abnormal noise or
vibration is produced.

Temperature,humidity,
dust content, harmful
gas, etc.

If input, output voltage
is abnormal

If the fastenings come
loose, if any signs show
overheat,discharging, or
too high dust content, or
the air piping is blocked
If there is abnormal
appearance

If the parts come loose Check visually

If the screws or bolts
come loose

Visual check

Visual and
audible check

Check visually,
by smelling and
feeling
Measure at
R, S, T and U, V,
W terminals
Check visually,
tighten the
fastenings, and
clean the related
parts

Check visually

Tighten the loose
screws or bolts

As per use
state
N abnormal
sound or
vibration

As per Section
2-1

As per standard
specifications

N abnormal
conditions

N abnormal
condition
N abnormal
condition
N abnormal
condition

“D” means daily check and “R” means regularly check.

“” means need daily check or regularly check

For inspection, do not disassemble or shake the parts without reason, and still less pull off the

If measuring is necessary, the user should note that much different results will be gained possibly if

In order to ensure the operation reliability of the frequency converter, in addition to regular

Section VIII

Part name Interval for replacement

Cooling fan 1~3 years

Filtering capacitor 4~5 years

PCB (printed circuit board) 5~8 years

8-3. Storage

The following actions must be taken if the frequency converter is not put into use immediately after

delivery to the user and need to keep well for the time being or stored for a long time:
※ Stored in a dry and adequately-ventilated place without dust and metal powder at the temperature

specified in the specifications.

※ If the frequency converter is not put into use after one year, a charge test should be made, so as to

resume the performance of the filtering capacitor of main circuit in it. For charging, a voltage
regulator should be used to slowly increase the input voltage of the frequency converter until it
reaches the rating, and the charge should last more than 1~2 hours. This test should be made at
least once a year.

※ Don’t perform breakdown test at random, for this test will cause shorter life of the frequency

converter. The insulation test must be performed after the insulation resistance is measured with a
500-volt megaohm and this value must not be less than 4M.

8-4. Measuring and Judgment

※ If the current is measured with the general instrument, imbalance will exists for the current at the

input terminal. Generally, differing by not more than 10% is normal. If it differs by 30%, inform
the factory to replace the rectification bridge, or check if the error of three-phase input voltage is
above 5V.

※ If the three-phase output voltage is measured with a general multi-meter, the reading is not

accurate due to the interference of carrier frequency and only for reference.

Section IX

117

118

Section IX Options

Section IX. Options

The series can acquire the peripheral equipment by user because of the different using condition and
requirement. See the wiring diagram as below:

9-1. MCCB OR ELCB

As power switch of the inverter, MCCB or ELCB can protect supply power, but can’t control

inverter to run

9-2. AC reactance

converter’s power factor obviously. It’s recommended that AC reactance will be used in the following
condition

or stop.

AC reactance is able to restrain the high harmonic wave of converter input current and improve

:

Section IX

※ The capacity of power source is ten times more than the capacity of converter.

※ SCR load or power factor compensated device with ON/OFF is connected with the same power

Section IX

supply.

※ Unbalanced 3-phase voltage is bigger (more than 3%).

The common size of AC input reactance:

U

X

V

Y

E

W

Z

F

Sharp size:

Inverter standard Size (mm)

Voltage

200V

230V

380V
460V

Capacity

(kW)

0.75 155 125 95 7 89 60 3.0

1.5 155 125 95 7 89 60 3.0

2.2 155 125 95 7 89 60 3.0

4 155 125 95 7 89 60 3.5

5.5 155 125 100 7 89 60 3.5

7.5 155 125 112 7 89 70 4.0

11 155 125 112 7 89 70 6.0

15 180 140 112 8 90 80 8.0

18.5 180 140 112 8 90 90 8.0

22 180 140 112 8 90 90 8.0

30 230 175 122 10 160 90 12.0

37 230 175 132 10 160 100 15.0

45 230 175 150 10 160 110 23.0

55 230 175 160 10 160 120 23.0

75 285 220 230 14 180 130 30.0

0.75 155 125 95 7 89 60 3.0

1.5 155 125 95 7 89 60 3.0

2.2 155 125 95 7 89 60 3.0

4 155 125 95 7 89 60 3.5

A B C D E F

Gross

Weight

(kg)

119

120

Section IX Options

Section

IX

Section IX Options

5.5 155 125 100 7 89 60 3.5

7.5 155 125 112 7 89 70 4.0

11 155 125 112 7 89 70 6.0

15 180 140 112 8 90 80 8.0

18.5 180 140 112 8 90 90 8.0

22 180 140 112 8 90 90 8.0

30 230 175 122 10 160 90 12.0

37 230 175 132 10 160 100 15.0

45 230 175 150 10 160 110 23.0

55 230 175 160 10 160 120 23.0

75 285 220 230 14 180 130 30.0

110 285 250 230 14 210 140 33.0

160 360 260 230 14 210 140 40.0

200 360 270 230 14 210 140 45.0

250 400 330 240 14 240 140 55.0

315 400 350 285 14 270 160 90.0

9-3. Noise filter

The filter is used to restrain the conduction of electrical magnetic wave interference noise produced
by the converter or shock the interferential form radio or momentary concussion. The common size of
3-phase EMI noise filter is shown as following: confirm the power supply is 3-phase three lines or
3-phase four lines or single phase. Earthling wire is as short as possible, try to place the filter near the
converter.

Please choose EMI filter when the converter is used in residential area, commercial area, science
area or other. Please need to prevent magnetic interference, or need meet CE, UL, and CSA standard.

Note: If needed the filter, please contact with our company.

Section IX

380V

Please choose POWTRAN BRAKING UNIT if you need more braking torque. Please refer to the
catalog of braking unit.

There is N braking unit inside the large capacity frequency converter. Please choose POWTRAN

BRAKING UNIT if you need braking.

11 13.6 2000

15 10 3000

18 8 4000

22 6.8 4500

0.75 750 120

1.5 400 300

2.2 250 300

4 150 500

5.5 100 500

7.5 75 780

11 50 1000

15 40 1500

9-6. output EMI filter

The fittings can restrain the disturbance noise and lead leak current produced in the output side.

9-7. AC output reactor

When the line from inverter to motor is longer than 20 meters, it can restrain the over-current caused

by the distributing current and the wireless disturbance of the inverter.

9-4. Connector

It can cut off the supply power in action of the system protection function, to prohibit fault enlarging.
But can’t control the motor start or stop by connector.

9-5. Braking Unit & braking resistor

There is braking unit inside when using “B” type frequency converter, the maximum braking torque
is 50%. Please choose braking resistor according to the following table:

Typ e

220V

Converter power

(kW)

0.75 200 120

1.5 100 300

2.2 70 300

4 40 500

5.5 30 500

7.5 20 780

Braking resistor

()

121

Braking resistor

Power (W)

122

ppe

d

Section X Quality Assurance

The product quality assurance is in accordance with the following regulations:

1. The manufacturer should take responsibility for below specific elements:

1-1. In domestic use (as calculated from the date of shipment)

shipped within one month should accept refund※ , replacement and repair.
shipped within three months should accept replacement and repair. ※
ship packages within 1※ 5 months should accept repair.

1-2. Goods exported overseas (excluding China) and shipped within six months, the local seller is

responsible for repair.

2. Regardless of when and where to use POWTRAN branded products are paid to enjoy lie-long

service.

3. All the distributors, agency or production place of POWTRAN in whole China can provide

after-sales service for powtarn product, their conditions of service as follows:
3-1. We provide a 3-level inspection service on the local selling place (including troubleshooting).
3-2. All services comply with the related after-sale service terms and conditions stated on the

agency agreement between powtran and distributors.

3-3. Buyers can pay to any Powtran agent if need any after-sales services (whether or not the

warranty).

4. If this product has some quality problem or product liability accidents, we will take the

responsibility to terms 1-1 or 1-2 at most. if users need more liability guarantee, please apply for
insurance company in advance to insure your own property insurance.

5. The product’s warranty period is one year from the date of shipment.

6. In the case of the following causes of failure, even in the warranty period is also a paid repair:

6-1. Incorrect operation (depending on the use of manual), or modified without permission to

repair the problems caused.
6-2. The problems caused by using the inverters beyond its standard specifications requirement.
6-3. Damage caused by drop down or improper handling.
6-4. Inverters components aged or failure caused by improper environment.
6-5. Due to an earthquake, fire, wind and water disasters, lightning, abnormal voltage or other

natural disasters and disasters, accompanied by the damage caused.
6-6. The damage during transport (Note: The mode of transport designated by the customer, the

company's help on behalf of the procedures for handling the transfer of goods).
6-7. When the manufacture’s brand, trademark, serial number, nameplate and other damage or can

not be recognized.
6-8. If the buyer has not paid full money according to purchase agreement.
6-9. The installation, wiring, operation, maintenance or other use of objective reality can not be

described to the company's service office.

7. Concerning refund, replacement and repair services, goods shall be returned powtran company,

after confirmed the attribution of responsibility then they are allowed to be returned or repaired.

Appendix I. RS485 Communication Protocol

Section X

I-1. Use introduce

This chapter introduces something about the install and handle of RS485 communication between inverter
and PLC, PC, factory computer.

RS485 standard interface

A

z Can communicate with all computer

z Using multi-drop link system, can link more to 127 inverters

n
ix I

z Completely isolated, and noise shield

z The user would use all types of RS232-485 inverter, if only the inverter had “automatic RTS

control” function inside.

I-2. Specification

Communication function

Items Specification

Communication baud rate 38400/19200/9600/4800/2400/1200 bps is selectable.

Communication Protocol Modbus protocol, RTU format

Interface methods

Data fumula 1 start bit, 8 data bits, 1 stop bit, invalid parity bit.

Slave address

Communication port A

Communication port B RJ45, 8-core shielded cable, fixed 19200bps.

Asynchronism communication methods, semi-duplex, the previous

high byte, low byte in the post, and low-effective-bit pre-emptive.

Slave addresses can be set up 1~ 127

0 for broadcast address, host address 128 for the proportion of

linkage, other addresses are reserved.

Isolated RS485 Communication Card，Ter min als SG+ , SG -

RS232 communication card，terminals TX232, RX232

Shield SH, Default 19200bps.

I-3. Communication connection

I-3-1. Definition for Communication port A:

z RS485 communication module installation

123

124

Appendix I Rs485 Communication Protocol

Appendix I

Appendix I Rs485 Communication Protocol

8K-RS485_S connect to 8KLCB control board

8K-RS485_S connect to 8KSCB control board

z A28 current inverter communication address 1~127 (If there are more than 1 inverters, don’t use

the same number);

z When using RS485 running control methods, set F04=0/1/2,choice RS485 running control method

Match register

White

Brown

White

Brown

120ohm 1/4W

SG+

SG-

N#2#

Inverter

brown

brown

TX

RX

RS485
converter

White

orange

White

Green

T+
T-

white

Blue

White

Blue

SG-

Inverter

SG+

orange

green

……

blue

Blue

SG-

1#

Inverter

SG+

GND

Appendix I

PC

I-3-2. Definition for

Communication

port B pins

Communication

B port signal

EIA/TIA T568A

EIA/TIA T568B

Communication port B：

1 2 3 4 5 6 7 8

GND +5V 485+ 485- 485+ 485- +5V GND

White

green

White

Orange

green

Orange

I-3-3. Data safety and reliability

z The number of inverter can be connected is no more than 127.

z Though the length of communication cable can add up to 1300m, considering the stability, the length

limit within 800m.

z All the control signal cable use the shield cable, and is linked to the signal terminal “SH” of RS485.

z Data packet using CRC (vertical lengthy test) frame detection to ensure data reliability.

z Completely isolated RS485 communication module to ensure reliable communications, support

z Link RS485 communication cables to inverter control terminals (SG+), (SG-).

z When using RS232-485 transform, connect Inverter “SG+” to RS485 “T+”, Inverter “SG-” to

RS485 “T-”.

z After Confirming connection again, turn on inverter power.

z If connection is right, set communication parameters as following:

z A29 baud rate 0：1200, 1：2400, 2：4800, 3：9600, 4：19200, 5：38400

125

hot-swappable, after modular access, you can enter the work.

z The system is tested in 6 kinds of baud rate: 0:1200, 1:2400, 2:4800, 3:9600, 4:19200, 5:38400

z However, if under deteriorating environmental conditions, lowering the baud rate can improve the

communication quality.

z Interval time of sending from frame to frame is more than 50 bytes.

I-4. Communication Protocol

Communication architecture is inverter as a slave, the computer as a host.

126

Appendix I Rs485 Communication Protocol

Appendix I

A

Appendix I Rs485 Communication Protocol

MODBUS protocol defines a simple protocol data unit (PDU) which has nothing to do with a basic

communication layer, Specific bus or network MODBUS protocol mapping can introduce some

additional domain from application data unit (ADU).

ADU

Frame start Frame end

The basic format description

I-4-1: Start of frame, End of frame

ddress field Function code Data CRC checksum

PDU

Interval≥ 3.5 bytes,

I-4-2: Slave Address
From the machine's local address, through the A28 parameter settings, one network can only one
local address uniquely identifed.
Setting range 1 ~ 127.

00H = 0 ID address is broadcast mailing address, 128 ~ 255 reserved.

I-4-3: Function Code
Host send commands, slave response.

z Function Code Categories

0x03＝read inverterp’s multiple function codes, at most can read 16 registers(register pair of byte)

Host command

Frame start

address

Interval3.5bytes 1 byte 1 byte 2 bytes 2 bytes 2 bytes

Slave

address

Function

code

Registers

address

Register

number

CRC

checksum

frame end

address

Interval3.5

bytes

Slave response

Frame start

address

Interval3.5bytes 1 byte 1 byte 1 byte

Slave

address

Function

code

Read

byte

Read content

2 bytes*register

number

CRC

checksum

2 bytes

frame end

address

Interval3.5

bytes

Note: Read content=2 bytes x register number

0x06＝write inverter 1 function code

Host command

Frame start

address

Interval 3.5

bytes

Slave response

Slave

address

1 byte 1 byte 2 bytes 2 bytes 2 bytes

Function

code

Registers

address

Register

data

CRC

checksum

frame end

address

Interval 3.5

bytes

127

Frame start

address

Interval3.5bytes 1 bytes 1 bytes 2 bytes 2 bytes 2 bytes Interval 3.5 bytes

Slave

address

Function

code

Registers

address

Register

data

CRC

checksum

frame end

address

0x10＝Write multiple function in inverter, at most can be written in 16 registers(register pair of

byte)

Host command

Appendix I

Frame start

address

Interval3.5bytes 1 byte 1 byte 2 b ytes 2 bytes 1 byte

Slave

address

Function

code

Register

address

Register

number

Register

content byte

Register

content

2bytes*register

number

CRC

checksum

2 bytes Interval3.5bytes

frame end

address

Slave response

Frame start

address

Interval3.5bytes 1 byte 1 byte 2 bytes 2 bytes 2 bytes Interval3.5bytes

Slave

address

Function code Register address

Register

number

CRC

checksum

frame end

address

0x01=Read multiple switch status

Host Command

Frame start

address

Interval3.5bytes 1 byte 1 byte 2 bytes 2 bytes 2 b ytes Interval3.5bytes

Slave

address

Function

code

address Switch number

CRC

checksum

frame end

address

Slave response

Frame start

address

Interval3.5bytes 1 byte 1 byte 1 byte(data N) N bytes 2 bytes Interval3.5bytes

Slave

address

Function

code

Read byte

number

switch

state

CRC

checksum

frame end

address

Note: read byte number N=output quanlity/8, if the remainder is not 0, read byte number is N=N+1

0x05=Write single switch status

Host Command

Frame start

address

Interval3.5bytes 1 byte 1 byte 2 bytes 2 bytes 2 bytes Interval3.5bytes

Slave

address

Function

code

Output address Output value

CRC

checksum

frame end

address

Note: output value 0xFF00, switch ON; output value 0x0000, switch OFF. Other values are illegal,

the switch does not work.

Slave response

Frame start

address

Interval3.5bytes 1 byte 1 byte 2 bytes 2 bytes 2 bytes Interval3.5bytes

Slave

address

Function

code

Output

address

Output

value

CRC

checksum

frame end

address

128

Appendix I Rs485 Communication Protocol

Appendix I

Appendix I Rs485 Communication Protocol

If slave response and get back to below function code, it means communications abnormal.

0xA0 =0x80+0x20= Invalid operation, setting under this state is invalid

0xA1 =0x80+0x21= function code is invalid

0xA2 =0x80+0x22= Fault record is empty

0xA3 =0x80+0x23= register address is invalid

0xA4 =0x80+0x24= slave is busy, EEPROM delay.

0xA5 =0x80+0x25= administrator restricted

0xA6 =0x80+0x26= set value is beyond limit.

0xA7 =0x80+0x27= CRC checksum error

0xA8 =0x80+0x28= frame format error

I-4-4: Register Address:

The register address includes two bytes, data setting is constituted by a two-byte.

Function code Register Address high byte Register Address low byte

Parameter group Parameter serial number
F 0x00 0～63
A 0x01 0～63

0x03read

inverter

multiple

function.code

parameter

0x03.read

inverter status

0x03read

inverter.fault

history record

0x06.write

inverter.single

o 0x02 0～71
H 0x03 0～55
U 0x04 0～15
P 0x05 0～15
E 0x06 0～23
C 0x07 0～47
b 0x08 0～23
y NOTE 1 0x09 0～23
S 0x0B 0～15

Status Status number

0x00 Running status NOTE 2

R 0x10

Fault record Fault status history record content

Fault history record 1
Fault history record 2
Fault history record 3
Fault history record 4
Fault history record 5

Register Address high byte Register Address low byte

Parameter group High byte Parameter serial number

0x20
0x21
0x22
0x23
0x24

0x01 Reserved status 1

0x02 Reserved status 2

0x03 Reserved status 3

0x00 Fault type NOTE 4

0x01 Set frequency

0x02 Actual frequency

0x03 Actual current

0x04 DC voltage

0x05 Running status NOTE 5

0x06 Running time

0x07 IGBT temperature

function.code

parameter,
only write

RAM

0x10.write

inverter

multiple

function.code

Appendix I

parameter,
only write

RAM

0x06.write

inverter

command

Function parameter write EEPROM, register address high byte=original register address high byte+0x80

0x06.write

inverter.single

function.code

parameter

0x10.write

inverter

multiple

function code

parameter

0x01.read

multiple

switch status

0x05.Write

single.switch

status

F 0x00 0～63
A 0x01 0～63
o 0x02 0～71
H 0x03 0～55
U 0x04 0～15
P 0x05 0～15
E 0x06 0～23
C 0x07 0～47
b 0x08 0～23
y NOTE 1 0x09 0～23

Command Command number

R 0x10

Register address high byte Register address low byte

parameter Parameter serial number
F 0x80 0～63
A 0x81 0～63
o 0x82 0～71
H 0x83 0～55
U 0x84 0～15
P 0x85 0～15
E 0x86 0～23
C 0x87 0～47
b 0x88 0～23
y NOTE 1 0x89 0～23

Register address high byte Register address low byte

Switch classify address Parameter value

Running status 0x00

129

data

0x00 Running command NOTE 3

0x01 Reserved command 1

0x02 Reserved command 2

0x03 Reserved command 3

Control

0

method

1 reserved

Running

2

status

Direction

3

status

Speed up

5,4

status

6 upper

130

0 V/F control

1 SV control

0 stop

1 run

0 reverse

1 forward

00 stop

01 acceleration

10 deceleration

11 uniform speed

0 Upper frequency

Appendix I Rs485 Communication Protocol

Appendix I

t

Appendix I Rs485 Communication Protocol

frequency

Lower

7

frequency

JOG

8

running

9 Reserved

10 Reserved

11 Reserved

Fault

12

confirm

Direction

13

status

JOG

14

status

Fault

15

status

0 DI1 input

1 DI2 input

2 DI3 input

3 DI4 input

4 DI5 input

Input.terminal function 0x01

5 DI6 input

6 DI7 input

7 DI8 input

8 AI1 input

9 AI2 input

10 AI3 input

131

not arrive

1 Arrive

lower

0

frequency

1 Arrive

No JOG

0

running

1 JOG running

0 Confirmed fault

Unconfirmed

1

fault

0 No fault

1 alarming fault

0 No fault

Deceleration

1

stop fault

0 No fault

Urgent stop

1

fault

0 Invalid

1 Valid

0 Invalid

1 Valid

0 Invalid

1 Valid

0 Invalid

1 Valid

0 Invalid

1 Valid

0 Invalid

1 Valid

0 Invalid

1 Valid

0 Invalid

1 Valid

0 Invalid

1 Valid

0 Invalid

1 Valid

0 Invalid

1 Valid

0 O1 input

1 O2 input

Output.terminal function 0x02

2 O3 input

Appendix I

Fault type 0x03

Register address high byte Register address low byte

Switch classify address Parameter number

Running status 0x00

3 O4 input

0 E.OCP

1 reserved

2 E.OC3

3 reserved

4 E.OU Over voltage

5 E.LU Under voltage

6 E.OL Over load

7 E.UL Under load warming

8 E.PHI Phase loss

9 E.EEP EEPROM error

10 E.ntC Over heat

11 E.dAt Time limit fault

12 E.Set External fault

13 reserved

14 reserved

15 reserved

16 E.PId

17 E.OHt

18 E.OL2

19 E.PG

20 E.PHo

21 E.COA

22 E.COb

23 E.CAL

Run

0

command

132

0 Invalid

1 Valid

0 Invalid

1 Valid

0 Invalid

1 Valid

0 Invalid

1 Valid

System is disturbed or
impacted by instant over
current,over current sig­nal from current inspec­ted circuit or drive circui

Inverter output current
exceeded 3times the
motor rated current

PID regulation fault

Motor over heat fault

Motor over load fault

PG error

Inverter output phase
loss
Rs485.communication
port A fault
Rs485.communication
port B fault
Parameter
indentification fault

0stop

1 run

Appendix I Rs485 Communication Protocol

Appendix I

Appendix I Rs485 Communication Protocol

1 reserved

Direction

2

command

3 reserved

4 reserved

JOG

5

command

6 reserved

7 Free stop

reserved

8

reserved

9

reserved

10

reserved

11

reserved

12

reserved

13

reserved

14

reserved

15

0 DI1 input

1 DI2 input

2 DI3 input

3 DI4 input

4 DI5 input

Input.terminal function 0x01

Output.terminal function 0x02

5 DI6 input

6 DI7 input

7 DI8 input

8 AI1 input

9 AI2 input

10 AI3 input

0 O1 output

1 O2 output

133

0 reverse

1forward

0 reverse

1forward

0 reverse

1forward

0 invalid

1 valid

0 invalid

1 valid

0 invalid

1 valid

0 invalid

1 valid

0 invalid

1 valid

0 invalid

1 valid

0 invalid

1 valid

0 invalid

1 valid

0 invalid

1 valid

0 invalid

1 valid

0 invalid

1 valid

0 invalid

1 valid

0 invalid

2 O3 output

3 O4 output

NOTE 1：

Appendix I

Function 0x03 reading operation 0x06/0x10 writing operation

y00 reset the factory
setting

y01 upload parameter
onto keyboard

y02 latest fault record Valid operation Invalid operation

y03～y07
fault history record

y08reset fault record Return 0 Valid operation

y09 rated output current Valid operation Invalid operation

y10 rated output voltage Valid operation Invalid operation

y11 products series

y12 soft ware version Valid operation Invalid operation

y13 product date –year Valid operation Invalid operation

y14 product
month–date

y15 user decode input Valid operation Invalid operation

y16 user input password Valid operation Valid operation

y17 parameter group
protection

Return 0 Only can write into 5

Return 0 Invalid operation

Empty
record

New record 01H

Confirmed

record

80 0 3

Family

serial

The number should be decimalization.

Valid operation Invalid operation

Valid operation Valid operation

products

series

00H

02H

Input voltage

level

Invalid operation

Invalid operation

NOTE 2： running status byte

BIT 15 BIT 14 BIT 13 BIT 12 BIT

meaning

bit 11 BIT 10 BIT、 9 BIT 8 BIT

meaning reserved reserved reserved

bit 7 BIT 6 BIT 5 BIT 、 4 BIT

meaning

0：No fault
1：urgent stopping
fault

0：lower frequency
not arriving
1：arrive lower

0：No fault
1：decelerating fault

0：upper frequency
not arriving
1：arrive upper

0：No fault
1：alarming fault

00：stopping 01：accelerating
10：decelerating
11：running in a even speed

134

1 valid

0 invalid

1 valid

0 invalid

1 valid

0：confirmed fault
1：unconfirmed
fault

0：No JOG.
1：JOG running

Appendix I Rs485 Communication Protocol

Appendix I

Appendix I Rs485 Communication Protocol

frequency frequency

bit 3 BIT 2 BIT 1 BIT 0 BIT

meaning

0：running reverse
1：running forward

0: stopping
1: running

reserve

0: V/F control
1：SV control

NOTE 3：running command

bit 15 BIT 14 BIT 13 BIT 12 BIT

meaning reserve reserve reserve reserve

Bit 11 BI T 10 BIT 9 BIT 8 BIT

meaning reserve reserve reserve reserve

bit 7 BIT 6 BIT 5 BIT 4 BIT

meaning

0：No free-stop
1:free-stop command

reserve

0：JOG stopping
1：JOG running

bit 3 BIT 2 BIT 1 BIT 0 BIT

meaning reserve

0:reverse command
1:forward command

reserve

0:stop command
1:run command

NOTE 4：fault style code

reserve

18 E.OL2 Motor over load fault

19 E.PG PG error

20 E.PHo Inverter output loss phase

21 E.COA Rs485 communication port A fault

22 E.COb Rs485 communication port B fault

23 E.CAL Parameter indentification fault

Appendix I

NOTE 5： fault funning status

LED first position LED second position LED third position LED fourth position

Bit15-Bit12 Bit11-Bit8 Bit7-Bit4 Bit3-Bit0

Forward

F 0

Reverse

R 1

S 2 Stop command S 2 Stop status

E.g. keyboard display FF-A（return data 0001），said when fault occurs the inverter state：forward command、forward

state、accelerating running

F 0 Forward status A 1

R 1 Reverse status D 2

- 0 Separative sign

Accelerating

Decelerating

running in a even

E 3

S 0 stop

I-4-5：CRC checkup sum

Data meaning：data frame CRC checkup sum, using 2 bytes.
Checkup sum ＝ address + function code + data

Serial.number LED display Fault message

Enclose：CRC computation program：

0 E.OCP

1

reserve

2 E.OC3 Inverter output current exceeded 3 times of motor rated current

3

reserve

4 E.OU Over voltage

5 E.LU Under voltage

6 E.OL Over load

7 E.UL Under load warm

8 E.PHI Input phase loss

9 E.EEP EEPROM error

10 E.ntC Over heat

11 E.dAt Time limit fault

12 E.Set External fault

13

reserve

14

reserve

15

reserve

16 E.PId PID regulation fault

17 E.OHt Motor over heat fault

System is disturbed or impacted by instant over current, over current signal

from current inspected circuit or drive circuit

135

unsigned int cal_crc16 (unsigned char *data, unsigned int length)

{

unsigned int i,crc_result=0xffff;

while(length--)

{

crc_result^=*data++;

for(i=0;i<8;i++)

{

if(crc_result&0x01)

crc_result=(crc_result>>1)^0xa001;

else

crc_result=crc_result>>1;

}

}

crc_result=((crc_result&0xff)<<8)|(crc_result>>8);

return(crc_result);

136

Appendix I Rs485 Communication Protocol

Appendix I

Appendix I Rs485 Communication Protocol

I-5 Example of communication protocol:

Valid setup and communications under normal circumstances, the host command and slave responses

are as follows:

0x03= read inverter multiple function code, at most can read 16 registers (register 2bytes)

Host command read inverterF01 keyboard set frequency、 F02 frequency set up method

Slave address Function code Register address Register number CRC checksum

0x08 0x03 0x0001 0x0002 0x9552

Slave response inverter F01 keyboard set frequency to 50.00Hz、F02 frequency set up method to 0（keyboard set frequency orRS485）

Slave address Function code Read byte number Read content CRC c hecksum

0x08 0x03 0x04 0x1388,0x0000 0xE79D

Read byte number=2byte*register number

0x06＝write inverter single function code

Host command set up inverter F01 keyboard set frequency inverter to 50.00Hz

Slave address Function code Register address Register data CRC checksum

0x08 0x06 0x0001 0x1388 0xD5C5

Slave response inverter F01 keyboard set frequency to 50.00Hz

Slave address Function code Register address Register data CRC checksum

0x08 0x06 0x0001 0x1388 0xD5C5

0x10＝write inverter multiple function code, at most can write 16 registers(register 2bytes)

Host command inverter F01 ke yboard set frequency to 50.00Hz、 F02 frequency set up method to 0（keyboard set

frequency or RS485）

Slave

Function

address

0x08 0x10 0x0001 0x0002 0x04 0x1388,0x0000 0x9851

Register content byte number=2 bytes * register number

Slave response

Slave

address

0x08 0x10 0x0001 0x0002 0x1091

Register address

code

Function code

Register

address

Register

number

Register content byte

number

Register

number

CRC

checksum

Register content

CRC

checksum

Slave address Function code

0x08 0x01 0x0300 0x0020 0x3D0F

Salve response inverter low voltage (E.LU switch address 0x0305)

Slave address Function code Read byte number Switch state CRC checksum

0x08 0x01 0x04 0x20,0x00,0x00,0x00 0x6911

Note ：return byte ：4 bytes；

Appendix I

Return date in order：bit7-bit0, bit15-bit8, bit23-bit16, bit31-bit24

0x05＝write single switch status

Host command control inverter running

Slave address Function code Output address Output value CRC checksum

0x08 0x05 0x0000 0xFF00 0x8CA3

Slave response

Slave address Function code Output address Output value CRC checksum

0x08 0x05 0x0000 0xFF00 0x8CA3

Host command control inverter stop

Slave address Function code Output address Output value CRC checksum

0x08 0x05 0x0000 0x0000 0xCD53

Slave response

Slave address Function code Output address Output value CRC checksum

0x08 0x05 0x0000 0x0000 0xCD53

Note: set switch to 1,output value is 0xFF00;set switch to 0,output value is 0x0000.

Starter to end

address

Switch number CRC checksum

0x01＝read multiple switch status

Host command read inverter whether arrive lower frequency, or arrive upper frequency

Slave address Function code

0x08 0x01 0x0006 0x0002 0x5D53

Slave response inverter not arrive lower frequency nor upper frequency

Slave address Function code Read byte number Switch state CRC checksum

0x08 0x01 0x01 0x40 0x53E4

Host command read inverter fault

Starter to end

address

Switch number CRC checksum

137

138

Appendix II

Appendix II Instruction of the Proportional Linkage Function

Appendix II Instruction of the Proportional Linkage

Function

II-1. proportional linkage function:

The proportion interaction host computer:

Communication address = 128,
Communications port A is the communication port of host computer.
Communication port B can be used as the keyboard interface, or a PC host computer interface.
There is only one host inverter in one proportional linkage.
The host inverter control the running state, the slave inverter follow the host’s running state.

The proportion interaction slave computer:

Communication Address = 1 ~ 127,
Both communication port A and communication port B can be the communication port of slave

inverter.

In the slave inverter follow the host running and it can realize forced stopping by terminal or keyboard

if need.

For this function, the host computer should be set with the following parameters:

A28

Local communication address

128

For this function, the slave computer should be set with the following parameters:

F01 Keyboard set the frequency / Rs485 Command from proportion linkage Host

Keyboard setting frequency or RS485 0

AI1 the external analog setting 1

AI2 the external analog setting 2

F02 Frequency main set mode

Auxiliary setting mode of

F03

frequency set

relationship between main and

F04

auxiliary frequencies

AI3 the external analog setting 3

Keyboard potentiometer setting 4

Multi-segment digital voltage set 5

Digital Pulse Setting 6

Keyboard setting frequency or RS485 0

AI1 the external analog setting 1

AI2 the external analog setting 2

AI3 the external analog setting 3

Keyboard potentiometer setting 4

Multi-segment digital voltage setting 5

Digital Pulse Set 6

PID regulation mode 7

The main setting individual control 0

The auxiliary setting individual control 1

main + auxiliary 2

main -auxiliary 3

Appendix II

F05 Running control mode Proportional linkage control 4

Select this function, the slave inverter will follow the command of host inverter to run.
After select this function, it can also use keyboard, terminal and RS485 to control the

slave inverter’s running.

In the proportion of linkage during operation, if control by the keyboard, terminal,RS485
control, once the slave inverter stopped, the slave will N longer respond to the host command,
if need the slave once again to respond to host commands, it should control through the
keyboard, terminal and RS485, or after the host sends cease and desist commands then the
slave will respond the command again to run.

A28 communication address 1~127

A29 Baud rate Same as host

A30 Communication format Same as host

A55 Proportional linkage factor 0.10~10.00

During the proportional of linkage, the running state of slave inverter is controlled by the host

inverter.

Slave inverter F01 = proportional factor*the actual set frequency of host inverter of proportion

linkage.

Slaver S00 actual set frequency = slave F01 + frequency give and secondary amend +ascend/descend

adjusting.

II-2. Proportion linkage application Cases:

Features of proportional function:

1: the host inverter using the potentiometer to control the system speed and use the terminals to

control the forward/reverse running.
2: the slave follows the host running, the proportional linkage factor is 1.00
3: after get the running speed command from host inverter, the slave will store this command into to

F01.
4: the slave actual frequency is set through the keyboard or through terminal ascend/descend

adjusting.
5: the slave actual frequency is set through potentiometer adjusting.
6: the slave actual frequency = F01 + slave potentiometer adjusting + A40

The proportional linkage host settings:

F02 Frequency main set mode

A28 Communication address

A29 Baud rate 3: 9600bps

A30 Communication format 0

DI1 input terminal function select

o36

DI2 input terminal function select

o37

The proportional linkage slave settings:

F02 Frequency main set keyboard set the frequency or Rs485 0

F03 Auxiliary setting mode of AI1 external analog setting 1

(main *auxiliary)/maximum frequency 4

Maximum｛main, auxiliary｝ 5

Minimum｛main, auxiliary｝ 6

AI1 external analog setting

Host 128

1:forward running

2:reverse running

139

140

Appendix II Instruction of the Proportional Linkage Function

Appendix II

ppe

d

frequency set

relationship between main and

F04

auxiliary frequencies

F05 Running control mode Proportional linkage control 4

A28 Communication address 1~127

A29 Baud rate Same as host inverter

A30 Communication format Same as host inverter

o36 DI1 input terminal function select 39:free stopping

o37 DI2 input terminal function select 40:Up command

o38 DI3 input terminal function select 41:Down command

A43 Multi-function key MF1 8:MF key is appointed to be Up command

A44 Multi-function key MF2 9:MFkey is appointed to be Down command

main+Auxiliary 2

System wire connections:

Appendix III. RS485 PG Card Instruction

III-1. PI8000 PG can use arrange

type Encoder output method

1 +5V LINE DRIVER output

2 OPEN COLLECTOR output

3 Push-pull output type (complementary)

4 Voltage output type VOLTAGE

III-2. terminal function instruction

A

n
ix III

terminal Terminal function

PG signal input

Encoder output method:
1:+5V LINE DRIVER output；

JP1/JP2 jump to LD；
connect method：A+->A+ , B+->B+

R16/R17/R18/R19 disconnect.

2:OPEN COLLECTOR output；

JP1/JP2 jump tp OC；

Connect method: A ->A+ , B ->B+

R2/R4/R10/R11/R13/R15 disconect

3:Push-pull output type (complementary)；

A+ A- , B+ B-

Aout,Bout

JP1/JP2 jump tp OC；

Connect method: A ->A+ , B ->B+

R2/R4/R10/R11/R13/R15 disconnect

4:VOLTAGE output；

JP1/JP2 jump to OC；

Connect method: A ->A+ , B ->B+

R2/R4/R10/R11/R13/R15 disconnect

the adjustment of resistance associated with the output voltage：
V+ =5V, R16/R17/R28/R29＝200
V+ =12V，R16/R17/R28/R29=1K
V+ =24V，R16/R17/R28/R29＝2K
V+encoder power，through JP3 to select

PG signal output

Voltage output, voltage level determined by the encoder power supply
Encoder power, through JP3 to select：

A- ->A-, B- ->B-

141

V+

142

Appendix II Instruction of the Proportional Linkage Function

Appendix II

ppe

d

V

PGND encoder

Encoder PG pulses range 300~9999
maximum pulses frequency receiver 1MHz，when PG pulses=2500，maximum speed=400Hz

III-3. terminal connection:

Brake Unit

R
S
T

Earthing

（

Power

MCCB

）

DC Reactor

S(L2)

T(L3)

DC+2

PI8000
Inverter

P18000
PG

DC-DC+1

V+

PGND

A+

A-

B+

B-

Aout

Bout

Optional

U(T1)R(L1)
V(T2)
W(T3)

Aout

Bout

Motor

Earthing

（

Motor

Earthing

M
3~

）

V+

V-

A+

A-

B+

B-

PG

Appendix IV Converter Water Supply Controller Instruction

number E00 function Parameter setting definition Reference page

8 Inverter power 144

Special power

1

supply

13

14

Constant

2

pressure water

9

supply

Extruding

3

A

IV-1. Extend functions supplement

n

IV-1-1. E00=8: variable frequency power

iI

machine

P03 PID given signal selection, you can set through the keyboard, analog AI1, pulse and other means

15

to set a given voltage.

Given voltage is calculated as follows:
Given voltage:220VAC
Given voltage setting =220*1.414/500*100%=62.2%

Frequency Power specific parameters:

No. name scope unit meanings

E16 User parameter 1 0~9999 - Voltage increasing time 0

E17 User parameter 2

0~9999

In regulated power supply mode, the output and input voltage are both adjustable.
The increasing time and decreasing time of output voltage is adjusted by F09 and F10.
E16 is the voltage increasing time, the definition of the output voltage increasing time is

from9999 corresponds to 999.9 seconds.

E17 is the voltage decreasing time, the definition of the output voltage decreasing time is

from9999 corresponds to 999.9 seconds.

Voltage increasing/decreasing time just used to adjust the accelerate/decelerate time of output

frequency when the inverter running.

After the stopping command issued, the controller will stop the frequency output when the

output frequency decelerate to 0hz.

E18 User parameter 3

0~9999

For safety and reliability to ensure that the output voltage to bear the load within the system,

we need to define the maximum output voltage of the system.

If the system highest withstand voltage 250VAC，then a maximum outout voltage= 250；
E18=250。

Stable voltage

power

Constant

current power

144

-

Pump constant

pressure water

145

supply

Extruding

machine

-

Factory

setting

- Voltage decreasing time 0

- The max output voltage 0

143

IV-1-2. E00=13: Voltage regulation power

In this mode,connect AI2,AI3 to Hall,then measure the output voltage and use2Halls to do redundant

work to ensure the output voltage will not exceed the Hall voltage limitation.

In this mode, the following parameters should be adjusted:

144

Appendix IX Converter Water Supply Controller Instruction

Appendix IV

Appendix IX Converter Water Supply Controller Instruction

PID function group, P02 PID feedback signal selection.
AI2 is detected by analog and AI3 works as a redundant configuration to ensure the output voltage

safe and reliable.

When Feedback voltage is 100%, the corresponding Hall voltage is 500VAC, Hall output voltage is

5V.

Set o03=50%, o05=50%.
P03 PID given signal selection, you can set through the keyboard, analog AI1, pulse and other means

to set a given voltage.

Given voltage is calculates as follows:
When the given voltage =220VAC, given voltage setting =220*1.414/500*100%=62.2%
Other PID parameters are adjusted according to the site.
Under PID regulated power supply mode, the voltage acceleration and deceleration time is

controlled by PID parameters, it won’t affect by voltage acceleration and deceleration time.

Voltage regulation power specific parameters:

No. name Range unit Description

E16 User parameter 1 0~9999 - Voltage increasing time 0

E17 User parameter 2

In Voltage regulation power mode, the output and input voltage are both adjustable.
The increasing time and decreasing time of output voltage is adjusted by F09 and F10.
E16 is the voltage increasing time, the definition of the output voltage increasing time is from

9999 corresponds to 999.9 seconds.

E17 is the voltage decreasing time, the definition of the output voltage decreasing time is from

9999 corresponds to 999.9 seconds.

Voltage increasing/decreasing time just used to adjust the accelerate/decelerate time of output

frequency when the inverter running.

After the stopping command sent, the controller will stop the frequency output when the output

frequency decelerate to 0 hz.

E18 User parameter 3

For safety and reliability to ensure that the output voltage to bear the load within system,we

need to define the maximum output voltage of the system.

If the System highest withstand voltage 250VAC；
Then E18=250VAC.

0~9999

0~9999

- Voltage decreasing time 0

- Max output voltage 0

IV-1-3. Converter water supply controller instruction
IV-2-1. Constant water supply system parameters:

Factory

setting

Appendix IV

(3) Constant pressure water supply special parameters

Parameter Keyboard Display Setting

(4) Multi-function constant pressure water supply pump specific parameters

Parameter Keyboard Display Setting

(1) loading types with constant water supply function:

Parameter Keyboard display setting Meaning

E12 set to be single pump，no need the constant
pressure water supply interface board

E00 Load type 9

E12 set to multi-pump，need constant pressure
water supply interface board,while realize
4-pumps constant pressure water supply function.

(2) PID adjusting in constant water supply system

Parameter Keyboard Display Setting Meanings

F01 Keyboard set frequency 0 Keyboard set the frequency 0hz

145

Frequency main set mode

F02

Frequency auxiliary set mode

F03

main and auxiliary frequencies

F04

set

PID configure

P00

Feedback signal select

P02

Given signal select

P03

PID integration time

P05

PID differential time

P06

PID proportional gain

P07

Deviation Limit

P09

PID Display Range

P12

E01 Starting pressure deviation 10%

E02 Starting time delay 2.0

E03 Stop frequency 15.00

E04 stop time delay 2.0

E05 High pressure arrival value 80%

E06 Low pressure arrival 60%

E07 Timing to water supply 0000

E08 Timing shift alternation time 0.25

electromagnetic switching

E09

action delay

E10 Pumps shift judging time 100

0 Keyboard set frequency or RS485 set frequency.

7

2

0000

1~3

0~6

★

★

★

★

★

0.500

146

PID adjusting mode

main+ auxiliary set mode

single-way,the negative regulator, failure is not
action

External analog feedback signal given by the AI1
/ AI2 / AI3

Given signal can select the
keyboard/Rs485,potentiometers, digital voltage,
digital pulse, etc.

Setting according the site.

Setting according the site.

Setting according the site.

Setting according the site.

Setting according the site.

Meanings

Starting pressure deviation is 10%

Starting delay time is second.

stop at frequency 15HZ.

Stop time is 2 second.

feedback pressure reach and exceed the value of
this parameter, the I / O output terminal select
25, then it will output arrival signal.

when feedback pressure less than the low
pressure reached value of this parameter, the I /
O output terminal select 26, then it will output
arrival signal.

Timing to water supply function invalid

Meaning

According to first start first stop principles to con

- trol pump rotation,rotation time of 0.25 hours

When set up a station pump (drive motor) to
switch from variable frequency industry frequ ­ency, or from industry frequency to variable
frequency, and set its electromagnetic switching
action delay time is 0.5 seconds.

To set the determine time 100 seconds from inv

- erter output frequency reaches the upper limit
frequencies until increase pump (drive mo ­tor); or from inverter output frequency reaches
the lower limit frequencies until decrease pump
(drive motor).

Appendix IX Converter Water Supply Controller Instruction

Appendix IV

Appendix IX Converter Water Supply Controller Instruction

Constant Pressure Water

E11

Supply Configuration

E12 Multi-pump c onf iguration 1111

E13 Multi-pumps status ★

E14 Soft-start Pump Control 0000

Decelerating stop: When the inverter failure, the
rotation switching way is from variable freque -

0000

ncy pump to industry frequency and the pump
maintain the status.

N. 1 ~ 4 pumps are frequency controlled pump

Multi-pump control mode, displays the status of
each pump

Multi-pump control mode, set the control mode
of each pump, currently set to Full Stop

(5) constant pressure water supply IO parameter:

Parameter Keyboard Display Setting

25

o21~o24 Output signal select

o21~o24 Output signal select

o36~o46 Input terminal function select

o36~o46 Input terminal function select

o36~o46 Input terminal function select

o36~o46 Input terminal function select

o36~o46 Input terminal function select

o36~o46 Input terminal function select

o36~o46 Input terminal function select

o36~o46 Input terminal function select

o36~o46 Input terminal function select

o36~o46 Input terminal function select

High pressure arrival

26

Low pressure arrival

51

Pump 1 soft start

52

Pump 1 stop

53

Pump 2 soft starter

54

Pump 2 stop

55

Pump 3 soft starter

56

Pump 3 stop

57

Pump 4 soft state

58

Pump 4 stop

59

Manual shift command

60

Timing of water supply time-zero

Meanings

Appendix IV

(2) Dimension of water supply controller

fixed plate

IV-2-2. Application

It is special appendix for multiple pumps, which run with PI7000 family inverter to control the

multiple pumps water supply system effectively.

IV-2-3. Operation and connection notice:

◇ If it is power frequency motor, probable thermal relay must be used to protect motor.

◇ AC contactor with machinery chain equipment should be used between the power frequency

bypass and inverter output of aside the motor, lock logically on the electri control circuit to avoid
the short circuit of the power frequency and inverter output which damage the inverter and
equipments.

◇ The phase order of the power frequency to the motor should be the same with the phase order of

the inverter output to avoid the motor reverse. Please confirm the phase order and operate.

◇ When wiring the control signal of the inverter, please leave it away with the driving line, and do

not make them in the same wire, otherwise it will lead wrong action.

◇ Screen cable is used for Pressure set signal and pressure feedback signal.

IV-2-4. Dimension

(1) Dimension of water supply control card

fixed plate

×

the size of fixed plate

Note: The fixed plate can be fixed by any mounting hole in the figure.

fixed plate

147

148

Appendix IX Converter Water Supply Controller Instruction

Appendix IV

Appendix IX Converter Water Supply Controller Instruction

IV-2-5. IV-2-5. Frequency of water supply connection to the drive controller

Connection of water supply controller with inverter, the communniction cable and power
cable are connected as below：

IV-2-6. System diagram

Appendix IV

Remarks: ZK air switch KM contactor
JR thermo-relay M motor

IV-2-7. Water supply control mode

When several pumps supply water meanwhile, because of the different time(daytime and night),
different season(winter and summer), the variation of the water flow is great. To save energy and protect
the equipment, please run pumps as many as you need and stop pumps as many as you do not need.

Inverter will confirm the number of the running pumps according to the requirement of the pressure
close loop control. In the set range, only one pump is controlled by the inverter at the same time.

If the timing shift interval time is set 0.05~100.00, when the related running time is stable, inverter
inverter will shift up the pumps according to stop first or open first to ensure each pump has the chance to
run and avoid the pump rusted because of long time N use.

After the pumps run to the upper and lower, arrive the adding pumps or reducing pumps time,
inverter will add or redcue the pumps according to stop first or open first to ensure each pump can run
and avoid the pump rusted because of long time N use.

IV-2-8. Soft-start pump control mode

Set the soft start pump by E12 and through the input terminals o36 ~ o46, respectively controlled
soft-start pump start and stop.

Soft-start pump terminal control, stop first.

Soft-start pump is not controlled by constant pressure water supply system.Soft-start pump can be
used as sewage pumps and fire pumps

.

IV-2-9. Application Guide

149

3 Pumps constant pressure water supply + sewage pump

150

Appendix IX Converter Water Supply Controller Instruction

Appendix IV

Appendix IX Converter Water Supply Controller Instruction

(1) pump configurations: variable frequency pump 3 units, 15kW,1 unit sewage pump,15kW.

(2) The set pressure 0.8Mpa.

(3) pressure gauge options: pressure transmitter, DC 4 ~ 20mA output, 1.6Mpa.

(4) Inverter choice: PI8000 015F3 and WSC_RS485 water supply board.

(5) Hardware Connection.

(6) Parameter setting

① loading types with a constant pressure water supply function:

Parameter Keyboard Display Setting Meanings

Multi-pump constant pressure water supply, need constant

Loading type

E00

② PID adjust in constant pressure water supply

Parameter Keyboard Display Setting Meanings

F01 Keyboard set frequency

Frequency main set

F02

mode

Frequency secondary

F03

Appendix IV

set mode

elationship between
main and auxiliary

F04

frequencies given

F05 Running control mode

A29 baud rate 3 baud rate 9600

P00 PID configure

Feedback signal

P02

select

P03 Give signal select

P05 PID integration time

P06 PID differential time 0 Setting according the site.

P07 PID proportional gain 100.0 Setting according the site.

P09 Deviation Limit 5.0 Setting according the site.

P12 PID Display Range 1.6

9

pressure water supply interface board, while realize4pump

constant pressure water supply pump function.

0 Keyboard set the frequency 0hz

0 Keyboard set frequency or RS485 set frequency.

7 PID adjusting mode

2 main+ auxiliary set mode

3 Terminal control

0000 single-way, the negative regulator, failure is not action

3 External analog feedback signal given by the AI3

2 External analog given by AI2

0.250 Setting according the site.

adjust according actual requirement,display the actual pres

- sure value is160.0, it means1.6Mpa.

③ Constant pressure water supply specific parameters

Parameter Keyboard Display Setting Meanings

Starting pressure

E01

deviation

E02 Starting time delay 2.0 Starting delay time is second.

E03 shutdown frequency 15.00 shutdown at frequency 15HZ.

E04 Shutdown time delay 2.0 shutdown time is 2 second.

E05 High pressure arrival 80%

E06 Low pressure arrival 60%

10% Starting pressure deviation is 10%

hen feedback pressure reach and exceed the high pressure

reached value of this parameter, the I / O output terminal

select 25, then it will output arrival signal.

when feedback pressure less than the low pressure

reached value of this parameter, the I / O output terminal

select 26, then it will output arrival signal.

151

152

Appendix IX Converter Water Supply Controller Instruction

Appendix IV

Regular time water

E07

supply

④ Multi-function constant pressure water supply pump specific parameters

Parameter Keyboard Display Setting Meaning

E08 regular rotation

E08

interval

Electromagnetic

E09

switching action delay

Pump switch to judge

E10

the time

Constant Pressure

E11

Water Supply

Configuration

Multi-pump

E12

configuration

E13 Multi-pump status 1112

Soft-start Pump

E14

Control

0000 Regular time water supply function invaid

According first start first stop principles to control pump

0.25
rotation, rotation time of 0.25 hours

When set up a station pump (drive motor) to switch from

variable frequency industry frequency, or from industry

0.500
frequency to variable frequency, and set its electromagn -

etic switching action delay time is 0.5 seconds.

To set the determine time 100 seconds from inverter out -

put frequency reaches the upper limit frequencies until

100

increase pump (drive motor); or from inverter output

frequency reaches the lower limit frequencies until

decrease pump (drive motor).

Shutdown: When the inverter failure,the rotation switch -

0

ing way is from variable frequency pump to industry fre -

quency and the pump maintain the status.

N. 1 ~ 3 pumps are frequency controlled pump, pump 4

2111

is soft-starter controlled pump.

Multi-pump control mode, displays the status of each

pump

Multi-pump control mode, set the control mode of each

★

pump, i currently set to Full Stop

⑤ constant pressure water supply IO parameters:

Parameter

o21

o22

o23

o36

o37

o38

o39

o40

o41

Value read On

Keyboard Display

o1 input signal select 1

o2 input signal select 2

o3 input signal select 3

(DI1) input terminal
function selection

(DI2)input terminal
function selection

(DI3) input terminal
function selection

(DI4) input terminal
function selection

(DI5) input terminal
function selection

(DI6) input terminal
function selection

Setting

Va l ue

25 High pressure arrival

26 Low pressure arrival

1 Fault input alarm

1

39

59 Manual rotation command

60 Timing of water supply time-zero

55 Pump 3 soft starting

56 Pump 3 stopping

FWD

Free parking

Meanings

153

Powtran frequency inverter failure feedback form

Dear

Customers, in order to provide better service for you, please kindly complete the following form in

details:

Load and controls

Motor

power and

poles

Load Type

Control

Mode

Failure description

when

Failure

occurs

Failure Type

OC

abnormal

voltage

Other

display

fault

Board

Failure

Keyboard

Failure

Device

Failure

Output

abnormal

If the fault is not in above ranks, please describe below:

Failure description:

 Fan  Textile Machine
 Extruder  Injection machine
 Pump  other load

 V/F, No PG,  PG+ V/F PG+ Vector control

 when power on  when start run when after run some time
 when speed up  when speed down

 OC-P  OC-C  OC-FA OC-2

 OU  LU  OL  UL

 OH  E-FL  PH-O  PID
PG(PG Error) DATE(use date expired) EEPR(EEPROM)

 no display after power on  smoking after power on
 power board and relay does not pull –in.

 button failure  parameter can not be modified
 LED display miss segment  Knob malfunction

 burnt  fan does not turn  Power Resistors burned
 main circuit relay or contactor does not pull-in

 no output voltage  output voltage unbalance
 motor vibrations  Motor power inadequate

Motor rated

current

Speed mode

Frequency range

under normal

working

 Keyboard  terminals
 PID  PLC

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